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Brachial plexus neuroma at the truncated extremity|Cryoablation |55|Male
Brachial plexus neuroma at the truncated extremity|Cryoablation |55|Male
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A New System For Treating Prosthetic Arterial And Aortic Graft Infections
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New Devices For False Lumen Obliteration With TBADs: Indications And Results
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CMS Policy Update On Nonthermal Ablation
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A RCT Comparing Medical Treatment vs. Thrombolysis And First Rib Resection For Venous TOS - Paget Schroetter Syndrome With Subclavian Vein Thrombosis
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Cloud Based System For Image Fusion Techniques With Mobile C-Arms (The Cydar System): How Does It Work And Advantages For All Vascular Interventions
anatomyaorticaortoiliacAortoiliac occlusive diseasebasedBilateral Kissing StentsbodiesclinicalcontrastCydar EV (Cydar Medical) - Cloud SoftwaredecreasesderivedendovascularevarFEVARfluorofluoroscopyfusionhardwarehybridiliacimageimagesimagingmechanicaloverlaypatientpostureprocedureproximalqualityradiationreductionscanstandardstatisticallytechnologyTEVARTherapeutic / DiagnostictrackingvertebralZiehm ImagingZiehm RFD C-arm
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How To Tailor Activity Recommendations To Patients After Cervical Artery Dissection
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Optimal Anticoagulation Regimen For Patients Being Treated For ALI
acuteangioplastyanticoagulationaspirinatrialbleedingcategoryclinicalcomorbiditiesefficacyembolismextremityguidelinesheparininfrainguinalintraopintravenousischemiaischemiclimbminoritypatientsperformedpostopproximalrecurrentregardreperfusionstablestentingsystemictherapeuticthrombosisunderwentunfractionatedvascularVeithversusvitamin
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Update On How To Diagnose And Treat Mixed Arterial And Venous Ulcers
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Why Open Endarterectomy Is The Best Treatment For Common Femoral Artery Lesions: It Is Still The Gold Standard In Most Cases Despite What You May Read And Hear
amputationarterycommoncommon femoralembolizationendarterectomyendovascularfemoralfemoral arteryhematomaInterventionsmehtamorbiditymortalitypatencypatientsperioperativeprimaryrestenosisrevascularizationrotationalstentstentingstentssuperficialsurgicalsurvivalTECCO
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New Developments In The Treatment Of Venous Thoracic Outlet Syndromes
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advancedamputationbypasscentercontemporarydataendoendovascularevarextremityfailedlimblimbsocclusionsOpen Bypassoutcomespatencypatientpatientspercentrevascularizationrisksecondarystagesurgerytolerate
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Pitfalls Of Percutaneous EVAR (PEVAR) And How To Avoid Them
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Summary Of Thermal Ablation RCTs
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New Developments In Access Site Closure For Small Sheaths; For Large Sheaths
ambulationantegradearteryassessingcalcifiedCardival Medicalcathcath labCelt ACD (Vasorum) - Vascular Closure DeviceclosurecollagencomplicationcomplicationscompressionconsconsecutivedeploymentdevicedevicesdiscembolizationfemoralhemostasismanualminorminutespatientsprosrandomizedrequiringretrogradestainlesssurgicaltherapeutictimetrialVascade VCDvascularVascular Closure Deviceversusvisualize
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Importance Of Maintaining Or Restoring Deep Femoral Artery Flow In Open And Endo Revascularizations For CLTI
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acquiredarterialarteriogramarteriovenousavmscoilcollateralsconnectionsDeep vein trombosisduralDVTentityepisodeevarextensiveextremityfemoralFistulahistoryiliacinflammatorylesionlesionsocclusionpelvicpriorstentingstimulationswellingthrombosistreatedtreatmentuterineveinvenouswayne
Surgical vs. Endovascular Management Of Cephalic Arch Syndrome
Surgical vs. Endovascular Management Of Cephalic Arch Syndrome
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Transcript

And this is a 55-year-old fire fighter, who ended up with

up with a right upper extremity amputation, synovial sarcoma. And so, in ultra sound basically shows this brachial plexus neuroma, right here. This is an image showing the probe line longitudinally through the

brachial plexus neuroma. The black arrows down here show the brachial plexus with this big neuroma on top of it and that's the ablation probe through it. A kind of surgical oblique image basically showing the two probes do it. Here's that T2 image with fast sat showing that neuroma right here

in surgical plane. So again from a more traditional axio imaging approach, the scalene muscles are outlined in green here with the neuroma in red. And bone window showing the probe right into the neuroma splitting the scalene musculature and here's a soft tissue when the're showing

the same thing. So, this is kinda of borrowing a lot of things that actually Dr.Prologo who'll talk about in a second has turned is really kind of a pioneer in this space for it. This is literature from dorsal penile nerve ablation which is a technique

he developed for premature ejaculation. And similarly pudental neuralgia in 2013 and other people that he put together. And so I'm kind of piggy banking on top of him. He's kind of the captain of this ship but he's definitely made me a believer. I tell people he's taken me to the cyroablation for nerve pain church

and I'm definitely singing his praises at this point.

- [Speaker] Thanks for the opportunity to present today. I'm going to talk about a specific complication of REBOA, a spinal cord injury. These are my disclosures. REBOA utilization for trauma and hemorrhagic shock has really increased greatly over the last decade, as you've heard.

Comparative data with resuscitative thoracotomy, although not easy to do, appears favorable. Case series and some meta-analyses have suggested that there is a clinical benefit, as Dr. Hur also stated, an ideal time for balloon occlusion though is not clear. Less is better, but what is the optimal time frame?

Many reports don't even include occlusion times, although that's getting better as data matures. Animal studies have suggested a significant morbidity mortality with end-points increased at 60-and 90-minute occlusion times. In human studies, when balloon occlusion times have

been compared, they're shorter in survivors than in patients who died. We know that surgical cross-clamp of the aorta has long been associated with spinal cord ischemia risk. In a large metanalysis of blunt traumatic aortic injury repaired with open surgical techniques

and no distal perfusion adjunct, there was 19% risk of paralysis in humans. In porcine studies and sheep studies, prolonged REBOA has been associated with spinal cord injury as well. But rarely reported in humans and whether

that's a reporting bias because of mortality it's not clear. The advantage of studying defined times for REBOA in a non-human primate model were why we undertook this study. The bipedal model really analogous to human

in most respects with the spinal cord anatomy being very similar and the coagulation cascade being the same. Here was our design. We had three groups, one was an initial survival study and model development phase.

Group two and group three were comparing 60- and 30-minute REBOA in the olive baboon with a ten-day survival and particular intent to look at the end point of spinal cord ischemia. This is an example of a pre and during balloon inflation.

You can see the brachial and femoral pressures on the screen on the left show very low blood pressures and soon after balloon inflation you get restoration of normal tension in the brachial arterial line. For our study, we saw these end points that in the

60-minute balloon inflation that animals become quite hypertensive rather than normal tensive. First 30 minutes we had no animals that were in hypertension phase. There was a significantly higher metabolic price to pay with prolonged balloon inflation at

60 minutes with the average base deficit delta of about 18 per millimoles liter. We also saw elevated troponins in the 60-minute occlusion group compared to the 30-minute group. Some had values even over five nanograms per milliliter as well as systolic evidence of myocardial injury.

All animals in the 60-minute REBOA group had histological evidence of renal injury, although none of them had creatine elevated of greater than 1.5 base line at the 10-day end point. Thirteen percent of the animals had histologic and laboratory evidence of myocardial injury.

And 50% of the animals in the 60-minute group had paralysis and histologic evidence of spinal cord injury. These are some representative images that show cavitation in the ventral horns of the spinal cord with severe inflammatory infiltrate. These are some more unexpected findings that show

ischemic injury to the dorsal horns as well as the dorsal columns in some of the animals. Wide spread spinal cord injury are not confined to the anterior spinal artery distribution. In summary, 60-minutes of REBOA balloon inflation after profound hemorrhagic shock in a

nonhuman primate model has high survival, but high morbidity. Fifty percent spinal cord ischemia, metabolic derangement, myocardial strain and injury and renal histologic injury. But in this study, all of these major morbidities

were essentially mitigated by limiting balloon inflation time to 30 minutes. With this in mind, we recommend that zone 1 REBOA be limited to 30 minutes in humans and after 30 minutes, every effort should be made to intermittently deflate the balloon as tolerated to allow

some reperfusion to occur. Thank you so much.

- [Bill] Thank you Vikay. I think this is an interesting topic for many reasons but one of the key ones is that if you look at our health care policies by insurers, this tends to define our practice. So I looked at BlueCross BlueShield's policy and they say that treatment of the GSV or SSV

is medically necessary when there is demonstrated saphenous reflux and I looked for more and there was no more. That's all they said so they must think that reflux a time correlates with venous severity. So is this true?

I think, personally, that there are other things that are involved and that volume is really the key. Time, velocity and the diameter of the vein are likely all part of the process and we all know that obstruction

is also critically important as well and probably the worse patients are those that have both reflux and obstruction. Probably reflux is worse in the deep system but we know that large GSV and SSV patients can develop CEAP four to six symptoms

and do very well with saphenous ablations. And I think this is a nice analogy. I love this guy, it looks like he came off of his lawn chair to help the firefighters out but he's probably not going to do so much with his little garden hose now, is he?

So I think size and velocity do matter. What does the literature tell us? Chris Lattimer and his group have done an elegant set of studies looking at how various parameters correlate to air plethysmography and venous filling times. They did show that there is a correlation

between venous filling time and reflux time. However, other things were probably more correlated such as GSV diameter and reflux velocity. And in this nice study of 300 patients they found that there was a relatively weak correlation between reflux time and clinical severity

and their conclusion was that it was a good parameter to identify reflux but not for quantifying the severity. So here's how we use this clinically in my practice. So you see many patients such as this that have mixed venous disease.

53-year-old female, severe edema. You do her studies and she's got reflux in the deep and the superficial system. So how to we decide if saphenous ablation is going to help this patient or not and correct these symptoms, prevent further ulcerations?

So all reflux is not created equal. The top is a popliteal tracing where the maximum reflux velocity is about five centimeters per second versus the bottom one that's about thirty to forty centimeters per second

so these probably aren't going to behave similarly in when we look at them. So we studied this in 75 patients and reported this back in 2008. We look at the maximum reflux velocity in the popliteal vein to tell if these patients

would improve after we ablated their saphenous or not. We found that this was a significant predictor of both improvement in venous filling index and the venous clinical severity score so we think velocity really does matter. And this is where we're seeing this clinically.

This is a patient that was referred to me for a second opinion concerning whether she would need ablation of her great saphenous vein. And this is the reflux tracing and you can see the scale here is turned up so that this is a measurement of reflux at about two centimeters per second.

This was used to document abnormal reflux and to justify ablation of the saphenous. So I checked one of our tracings. This is what it looks like.

- Thank you very much. So this is more or less a teaser. The outcome data will not be presented until next month. It's undergoing final analysis. So, the Vici Stent was the stent in the VIRTUS Trial. Self-expanding, Nitinol stent,

12, 14, and 16 in diameter, in three different lengths, and that's what was in the trial. It is a closed-cell stent, despite the fact that it's closed-cell, the flexibility is not as compromised. The deployment can be done from the distal end

or the proximal end for those who have any interest, if you're coming from the jugular or not in the direction of flow, or for whatever reason you want to deploy it from this end versus that end, those are possible in terms of the system. The trial design is not that different than the other three

now the differences, there are minor differences between the four trials that three completed, one soon to be complete, the definitions of the endpoints in terms of patency and major adverse events were very similar. The trial design as we talked about, the only thing

that is different in this study were the imaging requirements. Every patient got a venogram, an IVUS, and duplex at the insertion and it was required at the completion in one year also, the endpoint was venographic, and those who actually did get venograms,

they had the IVUS as well, so this is the only prospective study that will have that correlation of three different imagings before, after, and at follow-up. Classification, everybody's aware, PTS severity, everybody's aware, the endpoints, again as we talked about, are very similar to the others.

The primary patency in 12 months was define this freedom from occlusion by thrombosis or re-intervention. And the safety endpoints, again, very similar to everybody else. The baseline patient characteristics, this is the pivotal, as per design, there were 170 in the pivotal

and 30 in the feasibility study. The final outcome will be all mixed in, obviously. And this is the distribution of the patients. The important thing here is the severity of patients in this study. By design, all acute thrombotic patients, acute DVT patients

were excluded, so anybody who had history of DVT within three months were excluded in this patient. Therefore the patients were all either post-thrombotic, meaning true chronic rather than putting the acute patients in the post-thrombotic segment. And only 25% were Neville's.

That becomes important, so if you look at the four studies instead of an overview of the four, there were differences in those in terms on inclusion/exclusion criteria, although definitions were similar, and the main difference was the inclusion of the chronics, mostly chronics, in the VIRTUS study, the others allowed acute inclusion also.

Now in terms of definition of primary patency and comparison to the historical controls, there were minor differences in these trials in terms of what that historical control meant. However, the differences were only a few percentages. I just want to remind everyone to something we've always known

that the chronic post-thrombotics or chronic occlusions really do the worst, as opposed to Neville's and the acute thrombotics and this study, 25% were here, 75% were down here, these patients were not allowed. So when the results are known, and out, and analyzed it's important not to put them in terms of percentage

for the entire cohort, all trials need to report all of these three categories separately. So in conclusion venous anatomy and disease requires obviously dedicated stent. The VIRTUS feasibility included 30 with 170 patients in the pivotal cohort, the 12 months data will be available

in about a month, thank you.

- So I'm going to be talking about allografts for peripheral graft infections. This is a femoral artery that's been replaced after a closure device infection and complication, and we've bypassed to the SFA and profunda femoris. These are my disclosures. So peripheral arterial infectious processes,

well the etiology either is primary or secondary. Primary can be from bacteremic states and seeding of ulcerated plaque or thrombus. Secondary reasons for infections can be the vast usage of percutaneous closure devices that really have flooded the market these days.

Prosthetic graft infections after either a bypass or patch in the femoral artery. So early onset infections usually are from break in sterility. Secondary infections can be from either wound breakdowns or late seeding of the prosthetic graft.

The presentation for these patients can be relatively minor such as cellulitis or draining sinus, or much more dramatic, such as sepsis or pseudoaneurysm or mycotic aneurysm. On the CT scan we can see infected mycotic aneurysm after infected closure device and bleeding complications.

The treatment is broad in range. Ligation is obviously one option, but it leads to a very high risk of major limb amputation. So ideally some form of reconstruction, either extra-anatomic through clean planes,

antibiotic graft as we heard from the previous speaker, the use of autologous replacement with deep vein, or we become big proponents of the use of cryopreserved arterial allografts for reconstruction. And much of this stems from our work from about 10 years ago, where we looked

at the use of aortic cryopreserved grafts for aortic graft infections. This was published about 10 years ago but we looked at a small series of patients with aortic infections. You can see the CT scan of an infected stent graft

and associated aneurysm. And then the intraoperative photo after we've resected the stent graft and replaced that segment of the aorta with a cryopreserved aortic segment. So using that as a springboard,

we then decided to look at the outcomes using these types of conduits, arterial conduits, for peripheral arterial reconstructions in contaminated or infected surgical fields. So retrospective review at our tertiary care center, we looked at roughly 60 patients over a 15-year period

and excluded any aortic-based reconstructions. So these are all peripheral reconstructions. Mean follow-up was 28 months. As you would expect, the distribution of treatment zones were primarily in the lower extremities, so 51 cases.

As you can see, there's a list of all the different types of cases that we treated. But then there were a few upper extremity visceral and then carotid. I've shown this slide before at this meeting in the past, with a carotid patch infection

that was treated after it had a blow-out, and it's obviously a infected aneurysm, and this was treated with resection and a cryopreserved arterial segment. Looking at our outcomes, the 30-day outcome showed a mortality rate of 9%.

The 30-day conduit-related complication rate was surprisingly low at 14%. We had four patients that had bleeding complications, four patients with recurrent infectious complications. All eight of those patients required a return back to the operating room for correction.

The late conduit-related complication rate was only 16%. As listed here, you can see there's only one case of reinfection, three cases of graft thrombosis, surprisingly only one major limb amputation, two pseudoaneurysms and one late bleeding complication.

And graphically depicted, you can see here, this area here is looking at the less than 30 days, this is primarily when the complications occur. When you get to six months, fewer complications, and then beyond six months, the primary complications that we would see are either thrombosis of the graft

or the development of late pseudoaneurysms, again relatively low. So in summary, I think peripheral arterial infectious complications can be treated with a cryopreserved arterial allografts. The advantage is it's a single stage operation,

maintains in-line flow, there's a low incidence of repeat infection. I think it's also important to mention that the majority of these patients had adjunctive muscle flap coverage to cover the large soft tissue defect

at the time of the operation. So I think that this is a valuable alternative conduit in a setting of peripheral arterial infections. Thank you.

- Good morning. I'd like to thank Dr. Veith and Symposium for my opportunity to speak. I have no disclosures. So the in Endovascular Surgery, there is decrease open surgical bypass. But, bypass is still required for many patients with PAD.

Autologous vein is preferred for increase patency lower infection rate. And, Traditional Open Vein Harvest does require lengthy incisions. In 1996 cardiac surgery reported Endoscopic Vein Harvest. So the early prospective randomized trial

in the cardiac literature, did report wound complications from Open Vein Harvest to be as high as 19-20%, and decreased down to 4% with Endoscopic Vein Harvest. Lopes et al, initially, reported increase risk of 12-18 month graft failure and increased three year mortality.

But, there were many small studies that show no effect on patency and decreased wound complications. So, in 2005, Endoscopic Vein Harvest was recommended as standard of care in cardiac surgical patients. So what about our field? The advantages of Open Vein Harvest,

we all know how to do it. There's no learning curve. It's performed under direct visualization. Side branches are ligated with suture and divided sharply. Long term patency of the bypass is established. Disadvantages of the Open Vein Harvest,

large wound or many skip wounds has an increased morbidity. PAD patients have an increased risk for wound complications compared to the cardiac patients as high as 22-44%. The poor healing can be due to ischemia, diabetes, renal failure, and other comorbid conditions.

These can include hematoma, dehiscense, infection, and increased length of stay. So the advantages of Endoscopic Vein Harvest, is that there's no long incisions, they can be performed via one or two small incisions. Limiting the size of an incision

decreases wound complications. It's the standard of care in cardiac surgery, and there's an overall lower morbidity. The disadvantages of is that there's a learning curve. Electro-cautery is used to divide the branches, you need longer vein compared to cardiac surgery.

There's concern about inferior primary patency, and there are variable wound complications reported. So recent PAD data, there, in 2014, a review of the Society of Vascular Surgery registry, of 5000 patients, showed that continuous Open Vein Harvest

was performed 49% of the time and a Endo Vein Harvest about 13% of the time. The primary patency was 70%, for Continuous versus just under 59% for Endoscopic, and that was significant. Endoscopic Vein Harvest was found to be an independent risk factor for a lower one year

primary patency, in the study. And, the length of stay due to wounds was not significantly different. So, systematic review of Endoscopic Vein Harvest data in the lower extremity bypass from '96 to 2013 did show that this technique may reduce

primary patency with no change in wound complications. Reasons for decreased primary patency, inexperienced operator, increased electrocautery injury to the vein. Increase in vein manipulation, you can't do the no touch technique,

like you could do with an Open Harvest. You need a longer conduit. So, I do believe there's a roll for this, in the vascular surgeon's armamentarium. I would recommend, how I use it in my practices is, I'm fairly inexperienced with Endoscopic Vein Harvest,

so I do work with the cardiac PA's. With increased percutaneous procedures, my practice has seen decreased Saphenous Vein Bypasses, so, I've less volume to master the technique. If the PA is not available, or the conduit is small, I recommend an Open Vein Harvest.

The PA can decrease the labor required during these cases. So, it's sometimes nice to have help with these long cases. Close surveillance follow up with Non-Invasive Arterial Imaging is mandatory every three months for the first year at least. Thank you.

- Dear Chairman, Ladies and Gentlemen, Thank you Doctor Veith. It's a privilege to be here. So, the story is going to be about Negative Pressure Wound Non-Excisional Treatment from Prosthetic Graft Infection, and to show you that the good results are durable. Nothing to disclose.

Case demonstration: sixty-two year old male with fem-fem crossover PTFE bypass graft, Key infection in the right groin. What we did: open the groin to make the debridement and we see the silergy treat, because the graft is infected with the microbiology specimen

and when identified, the Enterococcus faecalis, Staphylococcus epidermidis. We assess the anastomosis in the graft was good so we decided to put foam, black foam for irrigation, for local installation of antiseptics. This our intention-to treat protocol

at the University hospital, Zurich. Multi-staged Negative Pressure for the Wound Therapy, that's meets vascular graft infection, when we open the wound and we assess the graft, and the vessel anastomosis, if they are at risk or not. If they are not at risk, then we preserve the graft.

If they are at risk and the parts there at risk, we remove these parts and make a local reconstruction. And this is known as Szilagyi and Samson classification, are mainly validated from the peripheral surgery. And it is implemented in 2016 guidelines of American Heart Association.

But what about intracavitary abdominal and thoracic infection? Then other case, sixty-one year old male with intracavitary abdominal infection after EVAR, as you can see, the enhancement behind the aortic wall. What we are doing in that situation,

We're going directly to the procedure that's just making some punctures, CT guided. When we get the specimen microbiological, then start with treatment according to the microbiology findings, and then we downgrade the infection.

You can see the more air in the aneurism, but less infection periaortic, then we schedule the procedure, opening the aneurysm sac, making the complete removal of the thrombus, removing of the infected part of the aneurysm, as Doctor Maelyna said, we try to preserve the graft.

That exactly what we are doing with the white foam and then putting the black foam making the Biofilm breakdown with local installation of antiseptics. In some of these cases we hope it is going to work, and, as you see, after one month

we did not have a good response. The tissue was uneager, so we decided to make the removal of the graft, but, of course, after downgrading of this infection. So, we looked at our data, because from 2012 all the patients with

Prostetic Graft infection we include in the prospective observational cohort, known VASGRA, when we are working into disciplinary with infectious disease specialist, microbiologists, radiologist and surgical pathologist. The study included two group of patients,

One, retrospective, 93 patient from 1999 to 2012, when we started the VASGRA study. And 88 patient from April 2012 to Seventeen within this register. Definitions. Baseline, end of the surgical treatment and outcome end,

the end of microbiological therapy. In total, 181 patient extracavitary, 35, most of them in the groin. Intracavitary abdominal, 102. Intracavitary thoracic, 44. If we are looking in these two groups,

straight with Negative Pressure Wound Therapy and, no, without Negative Pressure Wound Therapy, there is no difference between the groups in the male gender, obesity, comorbidity index, use of endovascular graft in the type Samson classification,

according to classification. The only difference was the ratio of hospitalization. And the most important slide, when we show that we have the trend to faster cure with vascular graft infection in patients with Negative Pressure Wound Therapy

If we want to see exactly in the data we make uni variant, multi variant analysis, as in the initial was the intracavitary abdominal. Initial baseline. We compared all these to these data. Intracavitary abdominal with no Pressure Wound Therapy

and total graft excision. And what we found, that Endovascular indexoperation is not in favor for faster time of cure, but extracavitary Negative Pressure Wound Therapy shows excellent results in sense of preserving and not treating the graft infection.

Having these results faster to cure, we looked for the all cause mortality and the vascular graft infection mortality up to two years, and we did not have found any difference. What is the strength of this study, in total we have two years follow of 87 patients.

So, to conclude, dear Chairman, Ladies and Gentlemen, Explant after downgrading giving better results. Instillation for biofilm breakdown, low mortality, good quality of life and, of course, Endovascular vascular graft infection lower time to heal. Thank you very much for your attention.

(applause)

- [Speaker] Thank you. My disclosures. So upper extremity dvt occurs in 4-10% of all causes of venous thrombosis. And while a minority, dvt in the upper extremity can often be caused by thoracic outlet syndrome, effort thrombosis, occasionally

idiopathic venous thrombosis. The majority is more likely related to central venous catheters, pacemakers, cancer, etc. This is some of the presentation of someone with Paget Schroeder or venous thoracic outlet syndrome, we're all well aware of this.

Some features of this can be sudden onset of pain, discoloration and some of this subcutaneous collateral veins that we note. Initial treatment of this is traditionally with venous thrombolysis. Although the results are good, this thrombolysis can

be associated with bleeding complications, potential for renal insufficiency, prolonged dwell times, and increased cost. I think it's important that this is not just a talk about a technique but a technique in the context of an operation this is soon to come.

Whether you choose to take out the rib at the same setting or you choose to delay the operation by a week or two, by and large the complications associated with that venous thrombolysis are going to come back and haunt you in the next operations. I think that's the context of this talk.

One of the risks I just mentioned about some of these techniques is, that's sort of curious to me, is the acute kidney injury after AngioJet venous thrombolysis. You see here, this paper, of a hundred patients, 50 AngioJet, 50 catheter directed thrombolysis, shows a statistical significantly

increased risk of acute kidney failure in the AngioJet group. Eight fold odds ratio. The Indigo system enables operators to remove the thrombus in a single setting, while potentially reducing or eliminating the need for thrombolysis.

This has already been discussed by some of the prior speakers, you see the different iterations first introduced in 2014. The CAT8 is the largest device and you can see some of the features of this proprietary technology with the separator and the directional sheaths that

allow us to aspirate nicely. This continuous suction you see here, can be very nicely controlled with an on-off switch that minimizes blood loss. It's single operator design, very easy to set up, hands free aspiration, a very simple set up.

You also heard just recently about the volume that can be aspirated in 20 seconds you see, especially with the larger profile devices, quite impressive amount of thrombus can be removed. Again, with the careful control for blood loss. The directionality of the sheath is also important,

and you can see some of the different directionality sheaths. Here's a couple case examples of a Paget-Schroder patient comes in with an acute sudden onset of arm pain and swelling discoloration, and you can see the penumbra device being used to clean out that vein.

This is another example, a 25-year old male with acute right arm swelling, sort of a body lifter type, and you can see here, this is the separator that's being moved forward and backwards, in and out to help break out the thrombus. This is the CAT8 device.

The pre-intervention picture seen here, we're crossing the lesion with a wire and and you can see the post-intervention on the right. You, of course, have the venous compression from the first rib, thoracic outlet, but the vein is widely open and now we can go ahead and see

the specimen that's retrieved as you've seen other videos in the prior presentations. This, of course, is what we're left with at the time of surgery. I only bring this up to remind us that there is a second stage to this treatment,

which is the rib resection. A combined experience that I just want to put together, very small numbers of course but, 16 patients with thoracic outlet who presented and were treated with the Penumbra system. You can see here, some of the demographic data.

I'll just point out the symptoms, of course, pain, swelling in these patients, imaging mostly venous duplex, occasionally CT or MR venogram. They all of course get venography at the time of procedure. The extent of the thrombus in all of them was complete occlusion and you can see some

of the extent in the subclavian axillary veins. Site of access can be the brachial or the basilic vein. The operative details as well, shown here, and I'll just point out the estimated blood loss, it can be very reasonable, especially with some experience you can sort of control that

on-off valve and minimize blood loss with this technique. Adjunctive therapies are shown here and of course, maybe because we're a little bit stuck on our ways, we did have a fair number of adjunctive lytic therapy. There were only three patients who had overnight lysis. A lot of venoplasty done at the time of the procedure.

All veins remained patent until the day of the rib resection but I will point out that one of these patients did develop a significant complication with hemothorax. This is one of those patients who had overnight lysis. And I point that out to stress that perhaps

this is what we're trying to move away from. So, in conclusion, mechanicothrombectomy using Indigo device shows promising initial results. Minimal blood loss, one complication of the hemothroax with the overnight lytics. No renal insufficiency or distal embolization.

The practice pattern, I think, need to adjust away from routing lytics to additionally minimize complications prior to surgery. Thank you.

- I'm going to take it slightly beyond the standard role for the VBX and use it as we use it now for our fenestrated and branch and chimney grafts. These are my disclosures. You've seen these slides already, but the flexibility of VBX really does give us a significant ability to conform it

to the anatomies that we're dealing with. It's a very trackable stent. It doesn't, you don't have to worry about it coming off the balloon. Flexible as individual stents and in case in a PTFE so you can see it really articulates

between each of these rings of PTFE, or rings of stent and not connected together. I found I can use the smaller grafts, the six millimeter, for parallel grafts then flare them distally into my landing zone to customize it but keep the gutter relatively small

and decrease the instance of gutter leaks. So let's start with a presentation. I know we just had lunch so try and shake it up a little bit here. 72-year-old male that came in, history of a previous end-to-side aortobifemoral bypass graft

and then came in, had bilateral occluded external iliac arteries. I assume that's for the end-to-side anastomosis. I had a history of COPD, coronary artery disease, and peripheral arterial disease, and presented with a pseudoaneurysm

in the proximal juxtarenal graft anastomosis. Here you can see coming down the thing of most concern is both iliacs are occluded, slight kink in the aortofemoral bypass graft, but you see a common iliac coming down to the hypogastric, and that's really the only blood flow to the pelvis.

The aneurysm itself actually extended close to the renal, so we felt we needed to do a fenestrated graft. We came in with a fenestrated graft. Here's the renal vessels here, SMA. And then we actually came in from above in the brachial access and catheterized

the common iliac artery going down through the stenosis into the hypogastric artery. With that we then put a VBX stent graft in there which nicely deployed that, and you can see how we can customize the stent starting with a smaller stent here

and then flaring it more proximal as we move up through the vessel. With that we then came in and did our fenestrated graft. You can see fenestrations. We do use VBX for a good number of our fenestrated grafts and here you can see the tailoring.

You can see where a smaller artery, able to flare it at the level of the fenestration flare more for a good seal. Within the fenestration itself excellent flow to the left. We repeated the procedure on the right. Again, more customizable at the fenestration and going out to the smaller vessel.

And then we came down and actually extended down in a parallel graft down into that VBX to give us that parallel graft perfusion of the pelvis, and thereby we sealed the pseudoaneurysm and maintain tail perfusion of the pelvis and then through the aortofemoral limbs

to both of the common femoral arteries, and that resolved the pseudoaneurysm and maintained perfusion for us. We did a retrospective review of our data from August of 2014 through March of 2018. We had 183 patients who underwent endovascular repair

for a complex aneurysm, 106 which had branch grafts to the renals and the visceral vessels for 238 grafts. When we look at the breakdown here, of those 106, 38 patients' stents involved the use of VBX. This was only limited by the late release of the VBX graft.

And so we had 68 patients who were treated with non-VBX grafts. Their other demographics were very similar. We then look at the use, we were able to use some of the smaller VBXs, as I mentioned, because we can tailor it more distally

so you don't have to put a seven or eight millimeter parallel graft in, and with that we found that we had excellent results with that. Lower use of actual number of grafts, so we had, for VBX side we only had one graft

per vessel treated. If you look at the other grafts, they're anywhere between 1.2 and two grafts per vessel treated. We had similar mortality and followup was good with excellent graft patency for the VBX grafts.

As mentioned, technical success of 99%, mimicking the data that Dr. Metzger put forward to us. So in conclusion, I think VBX is a safe and a very versatile graft we can use for treating these complex aneurysms for perfusion of iliac vessels as well as visceral vessels

as we illustrated. And we use it for aortoiliac occlusive disease, branch and fenestrated grafts and parallel grafts. It's patency is equal to if not better than the similar grafts and has a greater flexibility for modeling and conforming to the existing anatomy.

Thank you very much for your attention.

- Good afternoon, Dr. Veith, organizer. Thank you very much for the kind invitation. I have nothing to disclose. In the United States, the most common cause of mortality after one year of age is trauma. So, thankfully the pediatric vascular trauma

is only a very small minority, and it happens in less that 1% of all the pediatric traumas. But, when it happens it contributes significantly to the mortality. In most developed countries, the iatrogenic

arterial injuries are the most common type of vascular injuries that you have in non-iatrogenic arterial injuries, however are more common in war zone area. And it's very complex injuries that these children suffer from.

In a recent study that we published using the national trauma data bank, the mortality rate was about 7.9% of the children who suffer from vascular injuries. And the most common mechanism of injury were firearm and motor vehicle accidents. In the US, the most common type of injury is the blunt type

of injury. As far as the risk factors for mortality, you can see some of them that are significantly affecting mortality, but one of them is the mechanism of injury, blunt versus penetrating and the penetrating is the risk factor for

mortality. As far as the anatomical and physiological consideration for treatment, they are very similar to adults. Their injury can cause disruption all the way to a spasm, or obstruction of the vessel and for vasiospasm and minimal disruption, conservative therapy is usually adequate.

Sometimes you can use papevrin or nitroglycerin. Of significant concern in children is traumatic AV fissure that needs to be repaired as soon as possible. For hard signs, when you diagnose these things, of course when there is a bleeding, there is no question that you need to go repair.

When there are no hard signs, especially in the blunt type of injuries, we depend both on physical exams and diagnostic tools. AVI in children is actually not very useful, so instead of that investigators are just using what is called an Injured Extremity Index, which you measure one leg

versus the other, and if there is also less than 0.88 or less than 0.90, depending on the age of the children, is considered abnormal. Pulse Oximetry, the Duplex Ultrasound, CTA are all very helpful. Angiography is actually quite risky in these children,

and should be avoided. Surgical exploration, of course, when it's needed can give very good results. As far as the management, well they are very similar to adults, in the sense that you need to expose the artery, control the bleeding, an then restore circulation to the

end organ. And some of the adjuncts that are using in adult trauma can be useful, such as use of temporary shunts, that you can use a pediatric feeding tube, heparin, if there are no contraindications, liberal use of fasciotomy and in the vascular technique that my partner, Dr. Singh will be

talking about. Perhaps the most common cause of PVI in young children in developed countries are iatrogenic injuries and most of the time they are minimal injuries. But in ECMO cannulation, 20-50% are injuries due to

ECMO have been reported in both femoral or carotid injuries. So, in the centers are they are doing it because of the concern about limb ischemia, as well as cognitive issues. They routinely repair the ECMO cannulation site.

For non-iatrogenic types, if is very common in the children that are above six years of age. Again, you follow the same principal as adult, except that these arteries are severely spastic and interposition graft must accommodate both axial and radial growths of these arteries, as well as the limb that it's been

repaired in. Primary repair sometimes requires interrupted sutures and Dr. Bismuth is going to be talking about some of that. Contralateral greater saphenous vein is a reasonable option, but this patient needs to be followed very, very closely.

The most common type of injury is upper extremity and Dr. McCurdy is going to be talking about this. Blunt arterial injury to the brachial artery is very common. It can cause ischemic contracture and sometimes amputation.

In the children that they have no pulse, is if there are signs of neurosensory deficit and extremity is cold, exploration is indicated, but if the extremity is pulseless, pink hand expectant treatment is reasonable. As far as the injuries, the most common, the deadliest injuries are related to the truncal injuries and the

mechanism severity of this injury dictates the treatment. Blunt aortic injuries are actually quite uncommon and endovascular options are limited. This is an example of one that was done by Dr Veith and you can see the arrow when the stent was placed and then moved.

So these children, the long-term results of endovascular option is unknown. So in summary, you basically follow many tenets of adult vascular trauma. Special consideration for repair has to do with the fact that you need to accommodate longitudinal

and radial growth and also endovascular options are limited. Ultimately, you need a collaborative effort of many specialists in taking care of these children. Thank you.

- I want to thank Dr. Veith for the invitation to present this. There are no disclosures. So looking at cost effectiveness, especially the comparison of two interventions based on cost and the health gains, which is usually reported

through disability adjusted life years or even qualities. It's not to be really confused with cost benefit analysis where both paramaters are used, looked at based on cost. However, this does have different implications from different stakeholders.

And we look, at this point, between the medical center or the medical institution and as well as the payers. Most medical centers tend to look at how much this is costing them

and what is being reimbursed. What's the subsequent care interventions and are there any additional payments for some of these new, novel technologies. What does the payers really want to know, what are they getting for the money,

their expenditures and from here, we'll be looking mainly at Medicare. So, background, we've all seen this, but basically, you know, balloon angioplasty and stents have been out for a while and the outcomes aren't bad but they're not great.

They do have continued high reintervention rates and patency problems. Therefore, drug technology has sort of emerged as a possible alternative with better patency rates. And when we look at this, just some, some backgrounds, when you look at any sort of angioplasty,

from the physician's side, we bill under a certain CPT code and it falls under a family of codes for reimbursement in the medical center called an APC. Within those, you can further break it down to the cost of the product.

In this situation, total products cost around 1400 dollars and the balloons are estimated to be 406 dollars in cost. However, in drug-coated balloons, there was an additional payment, which average, because they're such more expensive devices than the allotments and this had an additional payment.

However, this expired in January of this year. When you look at Medicare reimbursement guidelines, you'll see that on an outpatient hospital setting, there's a reimbursement for the medical center as well as for the physican which is, oops sorry, down eight percent from last year.

And they also publish a geometric mean cost, which is quite higher than we expected. And then the office based practice is also the reimbursement pattern and this is slated to go down also by a few percentage points.

When you look at, I'm sorry, when you look at stents, however, it's a different family of CPT codes and APC family also. Here you'll see the supply cost is much higher in the, I'm sorry, the stent in this category is actually 3600 dollars.

The average cost for drug-eluting stents, around 1500 dollars and the only pass through that existed was on the inpatient side of it. Again, looking at Medicare guidelines, the reimbursement will be going down 8 percent

for the outpatient setting and the geometric mean cost is 11,700. So, what we want to look at really is what is the financial impact looking at primary patency, target lesion revascularization based on meta analysis. And the reinterventions are where the real cost

is going to come into effect. We also want to look at, when it doesn't work and we do bailout stenting, what is the cost going to happen there, which is not often looked at in most of these studies. So looking at a hypothetical situation,

you've got 100 patients, any office based practice, the payee will pay about 5145. There's a pass through payment which averages 1700 dollars per stent. Now, if you look at bailout stenting, 18.5 percent at one year,

this is the additional cost that would be associated with that from a payer standpoint. Targeted risk for revascularization was 12 percent of additional costs. So the total one year cost, we estimated, was almost a million dollars

and the cost per primary patency limb at one year was 13 four. In a similar fashion, for drug-eluting stents, you'll see that there's no pass through payment, but although there is a much higher payer expenditure. The reintervention rate was about 8.4 percent

at one year for the additional cost. And you'll see here, at the one year mark, the cost per patent limb is about 12,600 dollars. So how 'about the medical center, looking at Medicare claims data, you'll see the average cost for them is 745,000,

the medical center. Additional costs listed at another 1500. Bailout renting, as previously, with relate to a total cost at one year of 1.2 million or at 16,900 dollars per limb. Looking at the drug-eluting stents,

we didn't add any additional costs because the drug-eluting stents are cheaper than the current system that is in there but the reinterventions still exist for a cost per patent limb at one year of 14 six. So in essence, a few other studies have looked

at some model, both a European model and in the U.S. where the number of reinterventions at two to five years will actually offset the additional cost of drug-eluting stents and make it a financially advantageous process.

And in conclusion, drug-eluting stents do have a better primary patency and a decreased TLR than drug-coated balloons or even other, but they are more expensive than conventional treatment such as balloon angioplasty and bare-metal stents.

There is a decreased reintervention rate and the bailout stenting, which is not normally accounted for in a financial standpoint does have a dramatic impact and the loss of the pass through makes me make some of the drug-coated balloons

a little more prohibitive in process. Thank you.

- Thank you (mumbles) and thank you Dr. Veith for the kind invitation to participate in this amazing meeting. This is work from Hamburg mainly and we all know that TEVAR is the first endovascular treatment of choice but a third of our patients will fail to remodel and that's due to the consistent and persistent

flow in the false lumen over the re-entrance in the thoracoabdominal aorta. Therefore it makes sense to try to divide the compartments of the aorta and try to occlude flow in the false lumen and this can be tried by several means as coils, plug and glue

but also iliac occluders but they all have the disadvantage that they don't get over 24 mm which is usually not enough to occlude the false lumen. Therefore my colleague, Tilo Kolbel came up with this first idea with using

a pre-bulged stent graft at the midportion which after ballooning disrupts the dissection membrane and opposes the outer wall and therefore occludes backflow into the aneurysm sac in the thoracic segment, but the most convenient

and easy to use tool is the candy-plug which is a double tapered endograft with a midsegment that is 18 mm and once implanted in the false lumen at the level of the supraceliac aorta it occludes the backflow in the false lumen in the thoracic aorta

and we have seen very good remodeling with this approach. You see here a patient who completely regressed over three years and it also answers the question how it behaves with respect to true and false lumen. The true lumen always wins and because once

the false lumen thrombosis and the true lumen also has the arterial pressure it does prevail. These are the results from Hamburg with an experience of 33 patients and also the international experience with the CMD device that has been implanted in more than 20 cases worldwide

and we can see that the interprocedural technical success is extremely high, 100% with no irrelevant complications and also a complete false lumen that is very high, up to 95%. This is the evolvement of the candy-plug

over the years. It started as a surgeon modified graft just making a tie around one of the stents evolving to a CMD and then the last generation candy-plug II that came up 2017 and the difference, or the new aspect

of the candy-plug II is that it has a sleeve inside and therefore you can retrieve the dilator without having to put another central occluder or a plug in the central portion. Therefore when the dilator is outside of the sleeve the backflow occludes the sleeve

and you don't have to do anything else, but you have to be careful not to dislodge the whole stent graft while retrieving the dilator. This is a case of a patient with post (mumbles) dissection.

This is the technique of how we do it, access to the false lumen and deployment of the stent graft in the false lumen next to the true lumen stent graft being conscious of the fact that you don't go below the edge of the true lumen endograft

to avoid (mumbles) and the final angiography showing no backflow in the aneurysm. This is how we measure and it's quite simple. You just need about a centimeter in the supraceliac aorta where it's not massively dilated and then you just do an over-sizing

in the false lumen according to the Croissant technique as Ste-phan He-lo-sa has described by 10 to 30% and what is very important is that in these cases you don't burn any bridges. You can still have a good treatment

of the thoracic component and come back and do the fenestrated branch repair for the thoracoabdominal aorta if you have to. Thank you very much for your attention. (applause)

- Good morning. It's a pleasure to be here today. I'd really like to thank Dr. Veith, once again, for this opportunity. It's always an honor to be here. I have no disclosures. Heel ulceration is certainly challenging,

particularly when the patients have peripheral vascular disease. These patients suffer from significant morbidity and mortality and its real economic burden to society. The peripheral vascular disease patients

have fivefold and increased risk of ulceration, and diabetics in particular have neuropathy and microvascular disease, which sets them up as well for failure. There are many difficulties, particularly poor patient compliance

with offloading, malnutrition, and limitations of the bony coverage of that location. Here you can see the heel anatomy. The heel, in and of itself, while standing or with ambulation,

has tightly packed adipose compartments that provide shock absorption during gait initiation. There is some limitation to the blood supply since the lateral aspect of the heel is supplied by the perforating branches

of the peroneal artery, and the heel pad is supplied by the posterior tibial artery branches. The heel is intolerant of ischemia, particularly posteriorly. They lack subcutaneous tissue.

It's an end-arterial plexus, and they succumb to pressure, friction, and shear forces. Dorsal aspect of the posterior heel, you can see here, lacks abundant fat compartments. It's poorly vascularized,

and the skin is tightly bound to underlying deep fascia. When we see these patients, we need to asses whether or not the depth extends to bone. Doing the probe to bone test

using X-ray, CT, or MRI can be very helpful. If we see an abcess, it needs to be drained. Debride necrotic tissue. Use of broad spectrum antibiotics until you have an appropriate culture

and can narrow the spectrum is the way to go. Assess the degree of vascular disease with noninvasive testing, and once you know that you need to intervene, you can move forward with angiography. Revascularization is really operator dependent.

You can choose an endovascular or open route. The bottom line is the goal is inline flow to the foot. We prefer direct revascularization to the respective angiosome if possible, rather than indirect. Calcanectomy can be utilized,

and you can actually go by angiosome boundaries to determine your incisions. The surgical incision can include excision of the ulcer, a posterior or posteromedial approach, a hockey stick, or even a plantar based incision. This is an example of a posterior heel ulcer

that I recently managed with ulcer excision, flap development, partial calcanectomy, and use of bi-layered wound matrix, as well as wound VAC. After three weeks, then this patient underwent skin grafting,

and is in the route to heal. The challenge also is offloading these patients, whether you use a total contact cast or a knee roller or some other modality, even a wheelchair. A lot of times it's hard to get them to be compliant.

Optimizing nutrition is also critical, and use of adjunctive hyperbaric oxygen therapy has been shown to be effective in some cases. Bone and tendon coverage can be performed with bi-layered wound matrix. Use of other skin grafting,

bi-layered living cell therapy, or other adjuncts such as allograft amniotic membrane have been utilized and are very effective. There's some other modalities listed here that I won't go into. This is a case of an 81 year old

with osteomyelitis, peripheral vascular disease, and diabetes mellitus. You can see that the patient has multi-level occlusive disease, and the patient's toe brachial index is less than .1. Fortunately, I was able to revascularize this patient,

although an indirect revascularization route. His TBI improved to .61. He underwent a partial calcanectomy, application of a wound VAC. We applied bi-layer wound matrix, and then he had a skin graft,

and even when part of the skin graft sloughed, he underwent bi-layer living cell therapy, which helped heal this wound. He did very well. This is a 69 year old with renal failure, high risk patient, diabetes, neuropathy,

peripheral vascular disease. He was optimized medically, yet still failed to heal. He then underwent revascularization. It got infected. He required operative treatment,

partial calcanectomy, and partial closure. Over a number of months, he did finally heal. Resection of the Achilles tendon had also been required. Here you can see he's healed finally. Overall, function and mobility can be maintained,

and these patients can ambulate without much difficulty. In conclusion, managing this, ischemic ulcers are challenging. I've mentioned that there's marginal blood supply, difficulties with offloading, malnutrition, neuropathy, and arterial insufficiency.

I would advocate that partial or total calcanectomy is an option, with or without Achilles tendon resection, in the presence of osteomyelitis, and one needs to consider revascularization early on and consider a distal target, preferentially in the angiosome distribution

of the posterior tibial or peroneal vessels. Healing and walking can be maintained with resection of the Achilles tendon and partial resection of the os calcis. Thank you so much. (audience applauding)

- [Narrator] So my assignment is, CMS policy update on non-thermal ablation techniques, and as most of you know, there is not one National CMS policy, so there are a variety of local cover determinations or policies that we're going to look at. I may bore you for a couple minutes

but I found a surprise at the end. So I went to the website, CMS website, and looked up varicose vein LCDs and these seven came up, interestingly Novitas, everybody's favorite, didn't come. So I looked at separately, we're going to look at all these as well.

And here is Novitas, Novitas and their previous LCD had no mention of non-thermal techniques, but in this proposed LCD, which has a lot of people up in arms, they say that the non-thermal techniques are experimental, investigational, and unproven,

and therefore will not be covered. This is next LCDs, this is two from Medicare contractor Noridian, they go on to talk about sclerotherapy and foam sclerotherapy, but they are not going to cover it. And somewhat bizarrely these codes in red here,

which are for Venaseal and Verithena, are listed as indications for RF or laser ablation, which kind of shows you they don't know what they're talking about. And there is no mention of MOCA or Claravein. Wisconsin Physicians Services and other MAC contractor,

and I looked at their LCD, there is no mention of non-thermal techniques. Next up is First Coast Service Options, with these jurisdictions over here on the right. And they get down to the C-classification, VCSS score, and talk about compressive therapy and conservative therapy.

They do mention Clarivein or MOCA. However, they state that it does not meet the Medicare necessity for coverage, and so they won't. And there's absolutely no mention of Verithena or Venaseal in their LCD. Palmetto GBA is another contractor,

with these jurisdictions on the right, and they actually discuss and approve Varithena, microfoam sclerotherapy. They discuss it here in their LCD, they have some restrictions that the physician needs to be competent and experienced with Varithena,

and ultrasound, there is no mention of Clarivein or Venaseal in their LCD. And these are also the folks that tell us how to do stab phlebectomy with 2 mm incisions and a crochet hook. So don't use a 3 mm incision and a hemostat,

it'd probably get denied. Next is CGS Administrators, and this busy slide, they go on to talk about sclerotherapy quite a bit, and all these in the main body, what they are not going to cover for sclerotherapy. They mention that foam sclerotherapy

is basically the same as liquid sclerotherapy, and therefore will not cover it, and again no mention of other treatments of non-thermal techniques. Which brings us to the last LCD, which is National Government Services,

and amazingly they state that the accepted treatments for eliminating reflux and the great saphenous anterior accessory, and small saphenous vein, include RFA, laser, polidocanol, Venaseal, and Verithena. And even more interestingly, they use their Rationale for Determination for MOCA.

The amount and consistency of the data, in addition to the two recent systematic reviews and the strong recommendation of the American Venous Forum, have convinced NGS that Medicare coverage is met. And for PEM, Varithena, the combination of RCTs, meta-analyses, systematic reviews,

the strong recommendation of the AVF, and endorsements from the SVS, ACP, SCAI, and SIR, have convinced them that coverage is appropriate. And the same for Venaseal, same thing. This is craziness. On one Medicare hand,

you have Novitas saying that, treatment is experimental and unproven, and they won't cover it. And on the other Medicare hand, you have this contractor that says, based on the recommendations of the experts,

that it's appropriate, and will be covered. And this is the reason why we need a National Coverage Determination. So, to find out what your policy is, you have to go to the website, you have to find out who your provider is,

or contractor, and see what the policy cause it differs depending upon where you are. Thank you for your attention.

- Thank you chairman, ladies and gentlemen. I have no conflict of interest for this talk. So, basically for vTOS we have the well known treatment options. Either the conservative approach with DOAC or anticoagulation for three months or longer supported by elastic stockings.

And alternatively there's the invasive approach with catheter thrombolysis and decompression surgery and as we've just heard in the talk but Ben Jackson, also in surgeons preference, additional PTA and continuation or not of anticoagulation.

And basically the chosen therapy is very much based on the specific specialist where the patient is referred to. Both treatment approaches have their specific complications. Rethrombosis pulmonary embolism,

but especially the post-thrombotic syndrome which is reported in conservative treatment in 26 up to 66%, but also in the invasive treatment approach up to 25%. And of course there are already well known complications related to surgery.

The problem is, with the current evidence, that it's only small retrospective studies. There is no comparative studies and especially no randomized trials. So basically there's a lack of high quality evidence leading to varying guideline recommendations.

And I'm not going through them in detail 'cause it's a rather busy slide. But if you take a quick look then you can see some disparencies between the different guidelines and at some aspects there is no recommendation at all,

or the guidelines refer to selected patients, but they define how they should be selected. So again, the current evidence is insufficient to determine the most clinically and cost effective treatment approach, and we believe that a randomized trial is warranted.

And this is the UTOPIA trial. And I'm going to take you a bit through the design. So the research question underline this trial is, does surgical treatment, consisting of catheter directed thrombolysis and first rib section, significantly reduce post-thrombotic syndrome

occurrence, as compared to conservative therapy with DOAC anticoagulation, in adults with primary upper extremity deep vein thrombosis? The design is multicenter randomized and the population is all adults with first case of primary Upper Extremity

Deep Venous Thrombosis. And our primary outcome is occurrence of post-thrombotic syndrome, and this the find according the modified Villalta score. And there are several secondary outcomes, which of course we will take into account,

such as procedural complications, but also quality of life. This is the trial design. Inclusion informed consent and randomization are performed at first presentation either with the emergency department or outpatient clinic.

When we look at patients 18 years or older and the symptoms should be there for less than 14 days. Exclusion criteria are relevant when there's a secondary upper extremity deep vein thrombosis or any contra-indication for DOACs or catheter directed thrombolysis.

We do perform imaging at baseline with a CT venography. We require this to compare baseline characteristics of both groups to mainly determine what the underlying cause of the thrombosis being either vTOS or idiopathic.

And then a patient follows the course of the trial either the invasive treatment with decompression surgery and thrombolysis and whether or not PTA is required or not, or conservative treatment and we have to prefer DOAC Rivaroxaban or apixaban to be used.

Further down the patient is checked for one month and the Villalta score is adapted for use in the upper extremity and we also apply quality of life scores and scores for cost effectiveness analysis. And this is the complete flowchart of the whole trial.

Again, very busy slide, but just to show you that the patient is followed up at several time points, one, three, six, and 12 months and the 12 months control is actually the endpoint of the trial

And then again, a control CT venography is performed. Sample size and power calculation. We believe that there's an effect size of 20% reduction in post-thrombotic syndrome in favor of the invasive treatment and there's a two-side p-value of 0.05

and at 80% power, we consider that there will be some loss to follow up, and therefore we need just over 150 patients to perform this trial. So, in short, this slide more or less summarize it. It shows the several treatment options

that are available for these patients with Upper Extremity Venous Thrombosis. And in the trial we want to see, make this comparison to see if anticoagulation alone is as best as invasive therapy. I thank for your attention.

- Thank you. I have two talks because Dr. Gaverde, I understand, is not well, so we- - [Man] Thank you very much. - We just merged the two talks. All right, it's a little joke. For today's talk we used fusion technology

to merge two talks on fusion technology. Hopefully the rest of the talk will be a little better than that. (laughs) I think we all know from doing endovascular aortic interventions

that you can be fooled by the 2D image and here's a real life view of how that can be an issue. I don't think I need to convince anyone in this room that 3D fusion imaging is essential for complex aortic work. Studies have clearly shown it decreases radiation,

it decreases fluoro time, and decreases contrast use, and I'll just point out that these data are derived from the standard mechanical based systems. And I'll be talking about a cloud-based system that's an alternative that has some advantages. So these traditional mechanical based 3D fusion images,

as I mentioned, do have some limitations. First of all, most of them require manual registration which can be cumbersome and time consuming. Think one big issue is the hardware based tracking system that they use. So they track the table rather than the patient

and certainly, as the table moves, and you move against the table, the patient is going to move relative to the table, and those images become unreliable. And then finally, the holy grail of all 3D fusion imaging is the distortion of pre-operative anatomy

by the wires and hardware that are introduced during the course of your procedure. And one thing I'd like to discuss is the possibility that deep machine learning might lead to a solution to these issues. How does 3D fusion, image-based 3D fusion work?

Well, you start, of course with your pre-operative CT dataset and then you create digitally reconstructed radiographs, which are derived from the pre-op CTA and these are images that resemble the fluoro image. And then tracking is done based on the identification

of two or more vertebral bodies and an automated algorithm matches the most appropriate DRR to the live fluoro image. Sounds like a lot of gobbledygook but let me explain how that works. So here is the AI machine learning,

matching what it recognizes as the vertebral bodies from the pre-operative CT scan to the fluoro image. And again, you get the CT plus the fluoro and then you can see the overlay with the green. And here's another version of that or view of that.

You can see the AI machine learning, identifying the vertebral bodies and then on your right you can see the fusion image. So just, once again, the AI recognizes the bony anatomy and it's going to register the CT with the fluoro image. It tracks the patient, not the table.

And the other thing that's really important is that it recognizes the postural change that the patient undergoes between the posture during the CT scan, versus the posture on the OR table usually, or often, under general anesthesia. And here is an image of the final overlay.

And you can see the visceral and renal arteries with orange circles to identify them. You can remove those, you can remove any of those if you like. This is the workflow. First thing you do is to upload the CT scan to the cloud.

Then, when you're ready to perform the procedure, that is downloaded onto the medical grade PC that's in your OR next to your fluoro screen, and as soon as you just step on the fluoro pedal, the CYDAR overlay appears next to your, or on top of your fluoro image,

next to your regular live fluoro image. And every time you move the table, the computer learning recognizes that the images change, and in a couple of seconds, it replaces with a new overlay based on the obliquity or table position that you have. There are some additional advantages

to cloud-based technology over mechanical technology. First of all, of course, or hardware type technology. Excuse me. You can upgrade it in real time as opposed to needing intermittent hardware upgrades. Works with any fluoro equipment, including a C-arm,

so you don't have to match your 3D imaging to the brand of your fluoro imaging. And there's enhanced accuracy compared to mechanical registration systems as imaging. So what are the clinical applications that this can be utilized for?

Fluoroscopy guided endovascular procedures in the lower thorax, abdomen, and pelvis, so that includes EVAR and FEVAR, mid distal TEVAR. At present, we do need two vertebral bodies and that does limit the use in TEVAR. And then angioplasty stenting and embolization

of common iliac, proximal external and proximal internal iliac artery. Anything where you can acquire a vertebral body image. So here, just a couple of examples of some additional non EVAR/FEVAR/TEVAR applications. This is, these are some cases

of internal iliac embolization, aortoiliac occlusion crossing, standard EVAR, complex EVAR. And I think then, that the final thing that I'd like to talk about is the use with C-arm, which is think is really, extremely important.

Has the potential to make a very big difference. All of us in our larger OR suites, know that we are short on hybrid availability, and yet it's difficult to get our institutions to build us another hybrid room. But if you could use a high quality 3D fusion imaging

with a high quality C-arm, you really expand your endovascular capability within the operating room in a much less expensive way. And then if you look at another set of circumstances where people don't have a hybrid room at all, but do want to be able to offer standard EVAR

to their patients, and perhaps maybe even basic FEVAR, if there is such a thing, and we could use good quality imaging to do that in the absence of an actual hybrid room. That would be extremely valuable to be able to extend good quality care

to patients in under-served areas. So I just was mentioning that we can use this and Tara Mastracci was talking yesterday about how happy she is with her new room where she has the use of CYDAR and an excellent C-arm and she feels that she is able to essentially run two rooms,

two hybrid rooms at once, using the full hybrid room and the C-arm hybrid room. Here's just one case of Dr. Goverde's. A vascular case that he did on a mobile C-arm with aortoiliac occlusive disease and he places kissing stents

using a CYDAR EV and a C-arm. And he used five mils of iodinated contrast. So let's talk about a little bit of data. This is out of Blain Demorell and Tara Mastrachi's group. And this is use of fusion technology in EVAR. And what they found was that the use of fusion imaging

reduced air kerma and DSA runs in standard EVAR. We also looked at our experience recently in EVAR and FEVAR and we compared our results. Pre-availability of image based fusion CT and post image based fusion CT. And just to clarify,

we did have the mechanical product that Phillip's offers, but we abandoned it after using it a half dozen times. So it's really no image fusion versus image fusion to be completely fair. We excluded patients that were urgent/emergent, parallel endographs, and IBEs.

And we looked at radiation exposure, contrast use, fluoro time, and procedure time. The demographics in the two groups were identical. We saw a statistically significant decrease in radiation dose using image based fusion CT. Statistically a significant reduction in fluoro time.

A reduction in contrast volume that looks significant, but was not. I'm guessing because of numbers. And a significantly different reduction in procedure time. So, in conclusion, image based 3D fusion CT decreases radiation exposure, fluoro time,

and procedure time. It does enable 3D overlays in all X-Ray sets, including mobile C-arm, expanding our capabilities for endovascular work. And image based 3D fusion CT has the potential to reduce costs

and improve clinical outcomes. Thank you.

- Thank you very much. It's an hono ou to the committee for the invitation. So, I'll be discussing activity recommendations for our patients after cervical artery dissection. I have no relevant disclosures.

And extracranial cervical artery dissection is an imaging diagnosis as we know with a variety of presentations. You can see on the far left the intimal flap and double lumen in the left vertebral artery

on both coronal and axial imaging, a pseudoaneurysm of the internal carotid artery, aneurysmal degeneration in an older dissection, and an area of long, smooth narrowing followed by normal artery, and finally a flame-tipped occlusion.

Now, this affects our younger patients with really opposity of atherosclerotic risk factors. So, cervical artery dissection accounts for up to 25% of stroke in patients under the age of 45. And, other than hypertension, it's not associated with any cardiovascular risk factors.

There is a male predominance, although women with dissections seem to present about five years younger. And there is an indication that there may be a systemic ateriopathy contributing to this in our patients, and I'll show you some brief data regarding that.

So, in studies that have looked at vessel redundancy, including loops, coils, and in the video image, an S curve on carotid duplex. Patients with cervical artery dissection have a much higher proportion of these findings, up to three to four times more than

age and sex matched controls. They also have findings on histology of the temporal artery when biopsied. So one study did this and these patients had abnormal capillary formation as well as extravasation of blood cells between the median adventitia

of the superficial temporal artery. And there is an association with FMD and a shared genetic polymorphism indicating that there may be shared pathophysiology for these conditions. But in addition, a lot of patients report minor trauma around the time or event of cervical artery dissection.

So this data from CADISP, and up to 40% of cases had minor trauma related to their dissection, including chiropractic neck manipulation, extreme head movements, or stretching, weight lifting, and sports-related injuries. Thankfully, the majority of patients do very well after

they have a dissection event, but a big area of concern for the patient and their provider is their risk for recurrence. That's highest around the original event, about 2% within the first month, and thereafter, it's stable at 1% per year,

although recurrent pain can linger for many years. So what can we tell our patients in terms of reducing their risk for a recurrent event? Well, most of the methods are around reducing any sort of impulse, stress, or pressure on the arteries, both intrinsically and extrinsically,

including blood pressure control. I advise my patients to avoid heavy lifting, and by that I mean more than 30 pounds, and intense valsalva or isometric exercise. So shown here is a photo of the original World's Strongest Man lifting four

adult-sized males in addition to weights, but there's been studies in the physiology literature with healthy, younger males in their 20s, and they're asked to do a double-leg press, or even arm-curls, and with this exercise and repetitions, they can get mean systolic pressures,

or mean pressures up into the 300s, as well as heart rate into the 170s. I also tell my patients to avoid any chiropractic neck manipulation or deep tissue massage of the neck, as well as high G-force activities like a roller coaster.

There are some case reports of cervical artery dissection related to this. And then finally, what can they do about cardio? A lot of these patients are very anxious, they're concerned about re-incorporating exercise after they've been through something like this,

so I try to give them some kind of guidelines and parameters that they can follow when they re institute exercise, not unlike cardiac rehabilitation. So initially, I tell them "You can do light walking, but if you don't feel well,

or something's hurting, neck pain, headache, don't push it." Thereafter, they can intensify to a heart rate maximum of 70-75% of their maximum predicted heart rate, and that's somewhere between months zero and three, and then afterwards when they're feeling near normal,

I give them an absolute limit of 90% of their maximum predicted heart rate. And I advise all of my patients to avoid extreme exercise like Orange Theory, maybe even extreme cycling classes, marathons, et cetera. Thank you.

- I'd like the thank Doctor Veith for inviting me back to speak. I have no disclosures, we will be discussing some slight off-label use of the anitcoagulants. As we all know, acute limb ischemia occurs as a result of acute thrombosis of a native artery or bypass graft or embolism from a proximal

source, dissection, or trauma. The incidence is not insignificant, 15 cases per 100 000 persons per year, or interestingly about 10 to 16% of our vascular workload. Despite the relative frequency of this condition, there are relatively few guidelines to

guide us for anticoagulation therapy. The last set of guidelines for the American College of Chest Physicians regarding PAD gives some very brief, generic recommendations from 2012. They state, suggest immediate systemic anticoagulation with unfractionated heparin.

We suggest reperfusion over no reperfusion, which seems pretty obvious to an audience of vascular specialists. One of the challenges with acute limb ischemia is that it is a fairly heterogenous group. It can be thrombosis or embolism to the aorticiliac segments to the infrainguinal segments, and

there's also the patients who develop ALI from trauma. So we actually looked at the various phases of anticoagulation for acute limb ischemia and then we do, as with many institutions, utilize intravenous heparin at the time of the diagnosis, as well as obviously at the time of surgery,

but we found that there was a significant variation with regard to the early, post-operative anticoagulation regimens. One option is to give therapeutic intravenous heparin on an adjusted dose, but what we found in a significant minority of patients across the country actually,

is that people are giving this fixed mini-dose 500 unit an hour of heparin without any standardization or efficacy analysis. Then, obviously you go the long-term anticoagulation. We reviewed 123 patients who had ALI at our institution, who underwent surgical revascularization.

And they had the typical set of comorbidities you might expect in someone who has PAD or atheroembolism. In these patients, the Rutherford Classification was viable or marginally threatened in the majority, with about 25% having immediately threatened limb.

Various procedures were performed for these patients, including thromboembolectomy in the majority, bypass operations, angioplasty and stenting was performed in the significant minority and then primary amputation in the various selects few. We divided these patients into

the first four days of anticoagulation. Therapeutic with unfractionated heparin early on versus subtherapeutic or this mini-dose unfractionated heparin and we found that 29% of our patients were receiving the mini-dose unfractionated heparin, again without much efficacy analysis.

We used the International Society for Thrombosis and Haemostasis Anticoagulation Outcome Guidelines to look at the ischemic complications, as well as major and minor bleeding for these patients, and we identified actually not a significant rate of difference between the

subtherapeutic category and the therapeutic category of patients, with regard to mortality, with regard to recurrent limb ischemia, MI, VTE, or stroke, major amputation, and we actually didn't find because it's a fairly small study, any significant difference in major or minor bleeding for these patients.

So, we do feel that this small study did justify some efficacy of mini-dose unfractionated heparin because we didn't find that it was causing recurrent lower extremity thromboembolsim in these patients. Now on to long-term anticoagulation, for these patients, after that first three or four days

after the surgery, the options are long-term vitamin K antagonists, the DOAC's or vitamin K antagonists if you have atrial arrhythmia, or in the patients who had no other comorbidities, there really is not much guidance until recently. The compass trial was recently published in 2018

in stable PAD and carotid disease patients, identifying that rivaroxaban plus aspirin had a significant benefit over aspirin alone in patients who had stable PAD. And then, an upcoming trial, which is still ongoing currently in patients who underwent recent

revascularization, whether open or endo, is hopefully going to demonstrate that rivaroxaban, again has a role in patients with lower extremity ischemia. So in conclusion, there is relatively a scarcity of clinical data to help guide anticoagulation after acute limb ischemia.

Unfractionated heparin pre and intraop are standardized, but postop anticoagulation is quite variable. The mini-dose, we consider to be a reasonable option in the first few days to balance bleeding versus rethrombrosis, and fortunately we are having larger randomized clinical trials to help demonstrate the benefit of the DOACs and

aspirin in patients who are stable or post-revascularization for PAD, thank you.

- Thank you and thanks again Frank for the kind invitation to be here another year. So there's several anatomic considerations for complex aortic repair. I wanted to choose between fenestrations or branches,

both with regards to that phenotype and the mating stent and we'll go into those. There are limitations to total endovascular approaches such as visceral anatomy, severe angulations,

and renal issues, as well as shaggy aortas where endo solutions are less favorable. This paper out of the Mayo Clinic showing that about 20% of the cases of thoracodynia aneurysms

non-suitable due to renal issues alone, and if we look at the subset that are then suitable, the anatomy of the renal arteries in this case obviously differs so they might be more or less suitable for branches

versus fenestration and the aneurysm extent proximally impacts that renal angle. So when do we use branches and when do we use fenestrations? Well, overall, it seems to be, to most people,

that branches are easier to use. They're easier to orient. There's more room for error. There's much more branch overlap securing those mating stents. But a branch device does require

more aortic coverage than a fenestrated equivalent. So if we extrapolate that to juxtarenal or pararenal repair a branched device will allow for much more proximal coverage

than in a fenestrated device which has, in this series from Dr. Chuter's group, shows that there is significant incidence of lower extremity weakness if you use an all-branch approach. And this was, of course, not biased

due to Crawford extent because the graft always looks the same. So does a target vessel anatomy and branch phenotype matter in of itself? Well of course, as we've discussed, the different anatomic situations

impact which type of branch or fenestration you use. Again going back to Tim Chuter's paper, and Tim who only used branches for all of the anatomical situations, there was a significant incidence of renal branch occlusion

during follow up in these cases. And this has been reproduced. This is from the Munster group showing that tortuosity is a significant factor, a predictive factor, for renal branch occlusion

after branched endovascular repair, and then repeated from Mario Stella's group showing that upward-facing renal arteries have immediate technical problems when using branches, and if you have the combination of downward and then upward facing

the long term outcome is impaired if you use a branched approach. And we know for the renals that using a fenestrated phenotype seems to improve the outcomes, and this has been shown in multiple trials

where fenestrations for renals do better than branches. So then moving away from the phenotype to the mating stent. Does the type of mating stent matter? In branch repairs we looked at this

from these five major European centers in about 500 patients to see if the type of mating stent used for branch phenotype grafts mattered. It was very difficult to evaluate and you can see in this rather busy graph

that there was a combination used of self-expanding and balloon expandable covered stents in these situations. And in fact almost 2/3 of the patients had combinations in their grafts, so combining balloon expandable covered stents

with self expanding stents, and vice versa, making these analyses very very difficult. But what we could replicate, of course, was the earlier findings that the event rates with using branches for celiac and SMA were very low,

whereas they were significant for left renal arteries and if you saw the last session then in similar situations after open repair, although this includes not only occlusions but re-interventions of course.

And we know when we use fenestrations that where we have wall contact that using covered stents is generally better than using bare stents which we started out with but the type of covered stent

also seems to matter and this might be due to the stiffness of the stent or how far it protrudes into the target vessel. There is a multitude of new bridging stents available for BEVAR and FEVAR: Covera, Viabahn, VBX, and Bentley plus,

and they all seem to have better flexibility, better profile, and better radial force so they're easier to use, but there's no long-term data evaluating these devices. The technical success rate is already quite high for all of these.

So this is a summary. We've talked using branches versus fenestration and often a combination to design the device to the specific patient anatomy is the best. So in summary,

always use covered stents even when you do fenestrated grafts. At present, mix and match seems to be beneficial both with regards to the phenotype and the mating stent. Short term results seem to be good.

Technical results good and reproducible but long term results are lacking and there is very limited comparative data. Thank you. (audience applauding)

- Thank you, thanks for the opportunity to present. I have no disclosures. So, we all know that wounds are becoming more prevalent in our population, about 5% of the patient population has these non-healing wounds at a very significant economic cost, and it's a really high chance of lower extremity amputation

in these patients compared to other populations. The five-year survival following amputation from a foot ulcer is about 50%, which is actually a rate that's worse than most cancer, so this is a really significant problem. Now, even more significant than just a non-healing wound

is a wound that has both a venous and an arterial component to it. These patients are about at five to seven times the risk of getting an amputation, the end patients with either isolated venous disease or isolated PAD. It's important because the venous insufficiency component

brings about a lot more inflammation, and as we know, this is associated with either superficial or deep reflux, a history of DVT or incompetent perforators, but this adds an increasing complexity to these ulcers that refuse to heal.

So, it's estimated now about 15% of these ulcers are more of a mixed etiology, we define these as anyone who has some component of PAD, meaning an ABI of under point nine, and either superficial or deep reflux or a DVT on duplex ultrasound.

So we're going to talk for just a second about how do we treat these. Do we revascularize them first, do we do compression therapy? It has been shown in many, many studies, as with most things, that a multi-disciplinary approach

will improve the outcome of these patients, and the first step in any algorithm for these patients involves removing necrotic and infected tissue, dressings, if compression is feasible, based on the PAD level, you want to go ahead and do this secondary, if it's not, then you need to revascularize first,

and I'm going to show you our algorithm at Michigan that's based on summa the data. But remember that if the wounds fail to heal despite all of this, revascularization is a good option. So, based on the data, the algorithm that we typically use is if an ABI is less than point five

or a toe pressure is under 50, you want to revascularize first, I'll talk for a minute about the data of percutaneous versus open in these patients, but these are the patients you want to avoid compression in as a first line therapy.

If you have more moderate PAD, like in the point five to point eight range, you want to consider compression at the normal 40 millimeters of mercury, but you may need to modify it. It's actually been shown that that 40 millimeter of mercury

compression actually will increase flow to those wounds, so, contrary to what had previously been thought. So, revascularization, the data's pretty much equivocal right now, for these patients with these mixed ulcers, of whether you want to do endovascular or open. In diabetics, I think the data strongly favors

doing an open bypass if they have a good autogenous conduit and a good target, but you have to remember, in these patients, they have so much inflammation in the leg that wound healing from the surgical incisions is going to be significantly more difficult

than in a standard PAD patient, but the data has shown that about 60% of these ulcers heal at one year following revascularization. So, compression therapy, which is the mainstay either after revascularization in the severe PAD group or as a first line in the moderate group,

is really important 'cause it, again, increases blood flow to the wound. They've shown that that 40 millimeters of mercury compression is associated with a significant healing rate if you can do that, you additionally have to be careful, though,

about padding your bony areas, also, as we know, most patients don't actually keep their compression level at that 40, so there are sensors and other wearable technologies that are coming about that help patients with that, keeping in mind too, that the venous disease component

in these patients is really important, it's really important to treat the superficial venous reflux, EVLT is kind of the standard for that, treatment of perforators greater than five, all of that will help.

And I'm not going to go into any details of wound dressings, but there are plenty of new dressings that are available that can be used in conjunction with compression therapy. So, our final algorithm is we have a patient with these mixed arterial venous ulcers, we do woundcare debridement, determine the degree of PAD,

if it's severe, they go down the revascularization pathway, followed by compression, if it's moderate, then they get compression therapy first, possible treatment of venous disease, if it still doesn't heal at about 35 weeks, then you have to consider other things,

like biopsy for cancer, and then also consider revacularization. So, these ulcers are on a rise, they're a common problem, probably we need randomized control trials to figure out the optimal treatment strategies.

Thank you.

- Good morning. Thank you for the opportunity to speak. So thirty day mortality following unselected non-cardiac surgery in patients 45 years and older has been reported to be as high as 1.9%. And in such patients we know that postoperative troponin elevation has

a very strong correlation with 30-day mortality. Considering that there are millions of major surgical procedures performed, it's clear that this equates to a significant health problem. And therefore, the accurate identification of patients at risk of complications

and morbidity offers many advantages. First, both the patient and the physician can perform an appropriate risk-benefit analysis based on the expected surgical benefit in relation to surgical risk. And surgery can then be declined,

deferred, or modified to maximize the patient's benefit. Secondly, pre-operative identification of high-risk patients allows physicians to direct their efforts towards those who might really benefit from additional interventions. And finally, postoperative management,

monitoring and potential therapies can be individualized according to predicted risk. So there's a lot of data on this and I'll try to go through the data on predictive biomarkers in different groups of vascular surgery patients. This study published in the "American Heart Journal"

in 2018 measured troponin levels in a prospective blinded fashion in 1000 patients undergoing non-cardiac surgery. Major cardiac complications occurred overall in 11% but in 24% of the patients who were having vascular surgery procedures.

You can see here that among vascular surgery patients there was a really high prevalence of elevated troponin levels preoperatively. And again, if you look here at the morbidity in vascular surgery patients 24% had major cardiac complications,

the majority of these were myocardial infarctions. Among patients undergoing vascular surgery, preoperative troponin elevation was an independent predictor of cardiac complications with an odds ratio of 1.5, and there was an increased accuracy of this parameter

in vascular surgery as opposed to non-vascular surgery patients. So what about patients undergoing open vascular surgery procedures? This is a prospective study of 455 patients and elevated preoperative troponin level

and a perioperative increase were both independently associated with MACE. You can see here these patients were undergoing a variety of open procedures including aortic, carotid, and peripheral arterial. And you can see here that in any way you look at this,

both the preoperative troponin, the postoperative troponin, the absolute change, and the relative change were all highly associated with MACE. You could add the troponin levels to the RCRI a clinical risk stratification tool and know that this increased the accuracy.

And this is additionally shown here in these receiver operator curves. So this study concluded that a combination of the RCRI with troponin levels can improve the predictive accuracy and therefore allow for better patient management.

This doesn't just happen in open-vascular surgery patients. This is a study that studied troponin levels in acute limb ischaemia patients undergoing endovascular therapy. 254 patients all treated with endovascular intervention

with a 3.9% mortality and a 5.1% amputation rate. Patients who died or required amputation more frequently presented with elevated troponin levels. And the relationship between troponin and worse in-hospital outcome remains significant even when controlling for other factors.

In-hospital death or amputation again and amputation free survival were highly correlated with preoperative troponin levels. You can see here 16.9% in patients with elevated troponins versus 6% in others. And the cardiac troponin level

had a high hazard ratio for predicting worse in-hospital outcomes. This is a study of troponins just in CLI patients with a similar design the measurement of troponin on admission again was a significant independent predictor

of survival with a hazard ratio of 4.2. You can see here that the majority of deaths that did occur were in fact cardiac, and troponin levels correlated highly with both cardiac specific and all-cause mortality. The value of the troponin test was maintained

even when controlling for other risk factors. And these authors felt that the realistic awareness of likely long term prognosis of vascular surgery patients is invaluable when planning suitability for either surgical or endovascular intervention.

And finally, we even have data on the value of preoperative troponin in patients undergoing major amputation. This was a study in which 10 of 44 patients had a non-fatal MI or died from a cardiac cause following amputation.

A rise in the preoperative troponin level was associated with a very poor outcome and was the only significant predictor of postoperative cardiac events. As you can see in this slide. This clearly may be a "Pandora's box".

We really don't know who should have preoperative troponins. What is the cost effectiveness in screening everybody? And in patients with elevated troponin levels, what exactly do we do? Do we cancel surgery, defer it, or change our plan?

However, certainly as vascular surgeons with our high-risk patient population we believe in risk stratification tools. And the RCRI is routinely used as a clinical risk stratification tool. Adding preoperative troponin levels to the RCRI

clearly increases its accuracy in the prediction of patients who will have perioperative cardiac morbidity or mortality. And you can see here that the preoperative troponin level had one of the highest independent hazard ratios at 5.4. Thank you very much for your attention.

- Thank you. Historically, common femoral endarterectomy is a safe procedure. In this quick publication that we did several years ago, showed a 1.5% 30 day mortality rate. Morbidity included 6.3% superficial surgical site infection.

Other major morbidity was pretty low. High-risk patients we identified as those that were functionally dependent, dyspnea, obesity, steroid use, and diabetes. A study from Massachusetts General Hospital their experience showed 100% technical success.

Length of stay was three days. Primary patency of five years at 91% and assisted primary patency at five years 100%. Very little perioperative morbidity and mortality. As you know, open treatment has been the standard of care

over time the goal standard for a common femoral disease, traditionally it's been thought of as a no stent zone. However, there are increased interventions of the common femoral and deep femoral arteries. This is a picture that shows inflection point there.

Why people are concerned about placing stents there. Here's a picture of atherectomy. Irritational atherectomy, the common femoral artery. Here's another image example of a rotational atherectomy, of the common femoral artery.

And here's an image of a stent there, going across the stent there. This is a case I had of potential option for stenting the common femoral artery large (mumbles) of the hematoma from the cardiologist. It was easily fixed

with a 2.5 length BioBond. Which I thought would have very little deformability. (mumbles) was so short in the area there. This is another example of a complete blow out of the common femoral artery. Something that was much better

treated with a stent that I thought over here. What's the data on the stenting of the endovascular of the common femoral arteries interventions? So, there mostly small single centers. What is the retrospective view of 40 cases?

That shows a restenosis rate of 19.5% at 12 months. Revascularization 14.1 % at 12 months. Another one by Dr. Mehta shows restenosis was observed in 20% of the patients and 10% underwent open revision. A case from Dr. Calligaro using cover stents

shows very good primary patency. We sought to use Vascular Quality Initiative to look at endovascular intervention of the common femoral artery. As you can see here, we've identified a thousand patients that have common femoral interventions, with or without,

deep femoral artery interventions. Indications were mostly for claudication. Interventions include three-quarters having angioplasty, 35% having a stent, and 20% almost having atherectomy. Overall technical success was high, a 91%.

Thirty day mortality was exactly the same as in this clip data for open repair 1.6%. Complications were mostly access site hematoma with a low amount distal embolization had previously reported. Single center was up to 4%.

Overall, our freedom for patency or loss or death was 83% at one year. Predicted mostly by tissue loss and case urgency. Re-intervention free survival was 85% at one year, which does notably include stent as independent risk factor for this.

Amputation free survival was 93% at one year, which factors here, but also stent was predictive of amputation. Overall, we concluded that patency is lower than historical common femoral interventions. Mortality was pretty much exactly the same

that has been reported previously. And long term analysis is needed to access durability. There's also a study from France looking at randomizing stenting versus open repair of the common femoral artery. And who needs to get through it quickly?

More or less it showed no difference in outcomes. No different in AVIs. Higher morbidity in the open group most (mumbles) superficial surgical wound infections and (mumbles). The one thing that has hit in the text of the article

a group of mostly (mumbles) was one patient had a major amputation despite having a patent common femoral artery stent. There's no real follow up this, no details of this, I would just caution of both this and VQI paper showing increased risk amputation with stenting.

Thank you.

- So I'm just going to talk a little bit about what's new in our practice with regard to first rib resection. In particular, we've instituted the use of a 30 degree laparoscopic camera at times to better visualize the structures. I will give you a little bit of a update

about our results and then I'll address very briefly some controversies. Dr. Gelbart and Chan from Hong Kong and UCLA have proposed and popularized the use of a 30 degree laparoscopic camera for a better visualization of the structures

and I'll show you some of those pictures. From 2007 on, we've done 125 of these procedures. We always do venography first including intervascular intervention to open up the vein, and then a transaxillary first rib resection, and only do post-operative venography if the vein reclots.

So this is a 19 year old woman who's case I'm going to use to illustrate our approach. She developed acute onset left arm swelling, duplex and venogram demonstrated a collusion of the subclavian axillary veins. Percutaneous mechanical thrombectomy

and then balloon angioplasty were performed with persistent narrowing at the thoracic outlet. So a day later, she was taken to the operating room, a small incision made in the axilla, we air interiorly to avoid injury to the long thoracic nerve.

As soon as you dissect down to the chest wall, you can identify and protect the vein very easily. I start with electrocautery on the peripheral margin of the rib, and use that to start both digital and Matson elevator dissection of the periosteum pleura

off the first rib, and then get around the anterior scalene muscle under direct visualization with a right angle and you can see that the vein and the artery are identified and easily protected. Here's the 30 degree laparoscopic image

of getting around the anterior scalene muscle and performing the electrocautery and you can see the pulsatile vein up here anterior and superficial to the anterior scalene muscle. Here is a right angle around the first rib to make sure there are no structures

including the pleura still attached to it. I always divide, or try to divide, the posterior aspect of the rib first because I feel like then I can manipulate the ribs superiorly and inferiorly, and get the rib shears more anterior for the anterior cut

because that's most important for decompressing the vein. Again, here's the 30 degree laparoscopic view of the rib shears performing first the posterior cut, there and then the anterior cut here. The portion of rib is removed, and you can see both the artery and the vein

are identified and you can confirm that their decompressed. We insufflate with water or saline, and then perform valsalva to make sure that they're hasn't been any pneumothorax, and then after putting a drain in,

I actually also turn the patient supine before extirpating them to make sure that there isn't a pneumothorax on chest x-ray. You can see the Jackson-Pratt drain in the left axilla. One month later, duplex shows a patent vein. So we've had pretty good success with this approach.

23 patients have requires post operative reintervention, but no operative venous reconstruction or bypass has been performed, and 123 out of 125 axillosubclavian veins have been patent by duplex at last follow-up. A brief comment on controversies,

first of all, the surgical approach we continue to believe that a transaxillary approach is cosmetically preferable and just as effective as a paraclavicular or anterior approach, and we have started being more cautious

about postoperative anticoagulation. So we've had three patients in that series that had to go back to the operating room for washout of hematoma, one patient who actually needed a VATS to treat a hemathorax,

and so in recent times we've been more cautious. In fact 39 patients have been discharged only with oral antiplatelet therapy without any plan for definitive therapeutic anticoagulation and those patients have all done very well. Obviously that's contraindicated in some cases

of a preoperative PE, or hematology insistence, or documented hypercoagulability and we've also kind of included that, the incidence of postop thrombosis of the vein requiring reintervention, but a lot of patients we think can be discharged

on just antiplatelets. So again, our approach to this is a transaxillary first rib resection after a venogram and a vascular intervention. We think this cosmetically advantageous. Surgical venous reconstruction has not been required

in any case, and we've incorporated the use of a 30 degree laparoscopic camera for better intraoperative visualization, thanks.

- Thank you and thanks Craig, it's fun to have these debates with good colleagues, thoughtful colleagues. These are my disclosures for the talk. But pry my most important disclosure is I work in academic center with a dedicated Limb Preservation Center, very tertiary practice. And I perform both open and endovascular surgery

and actually my current lower extremity practice is probably about 60 to 65 percent endovascular so, I do both of these procedures. We already saw this slide about how the increase in endovascular intervention has grown. But, I would caution you to look a little more closely

at this outpace of decline in bypass surgery by more than three to one. I don't think this is an epidemic, I think it's a little bit of this, and a little bit of this. Everything looks like a nail when you only have a hammer

or a hammer when you only have a nail. So, what should we really be doing today? We should be trying to select the best thing for the right patient at the right time. And it really comes down to starting not with the lesion, but with the patient.

Start with assessing the patient's risk, what's their perioperative risk, what's their long-term survival, what are their goals for care? And then look at the limb itself, because not all limbs are the same.

There are minor ulcers, there's extensive and severe rest pain and there are large areas of tissue loss. And the WIfI system is good for that. And then let's look at the anatomy last. And when we're looking at it from the standpoint of what all the options are, endovascular we're looking

at what's the likelihood not just of technical success, but of hemodynamic gain and sustained patency for as long as a patient needs it. With bypass, we also have to look at other things. What kind of vein do they have, or what kind of target do they have?

And I think the bottom line here is in today's practice, it's kind of silly to say endo first for all patients, it's certainly not surgery first for all patients because they have complementary roles in contemporary practice. Well what's happening in the world out there,

this is the German CRITISCH registry, I'll just point out 12 hundred patients recently published only a couple of years ago, 24 percent of patients get bypass first. And if you look at who they are, not surprisingly they are the patients

with long occlusions and complex anatomy. They are out there, in fact most of these patients have multi-segment disease, as Craig pointed out. Here's some contemporary data that you haven't seen yet because it's in press, but this is VQI data looking at 2003 to 2017.

I'll point out just in the last 2013 years, still, if you looked at unique patients, not procedures, one-third of the patients are getting a bypass first. And if you define risk groups considering what might be a low risk patient as a three percent mortality and survival greater than 70 percent,

and a high risk patient, you can put these patients into buckets and in fact, of all the patients getting lower extremity revascularization and VQI today, 80 percent of them would be called low risk based on this definition. So, most patients are not high risk patients

who don't have long-term survival. In fact, this is current VQI data. If you're a low risk patient in that cohort, your five year survival actually is over 70 percent. So there's a lot of these patients actually today with better CLO medical therapy that are actually

living longer and are not that high risk. We talked about the BASIL trial already, and he pointed out how the early results were similar, but what we learned also with BASIL, that if you've got a bypass as a secondary procedure, or if you got a bypass with a prosthetic,

you simply did not do as well. That doesn't mean that the initial endovascular revascularization caused the bypass failure, but it means that secondary bypass surgery does not work as well. And when Dr. Bradbury looked at this data

over a longer period of time now going over many more years, there's a consistent inferior outcome to the patients who had their bypass after failed angioplasty in comparison to bypass as the initial strategy. This is not an isolated finding. When we looked in the VSGNE data over a,

more than 3000 patients at the impact of restenosis on subsequent treatment failure, we found that whether patients had a failed previous PVI or bypass, their secondary bypass outcomes were inferior, and the inferiority continued to get worse with time.

These bypasses just don't perform as well. Unfortunately, if we only do bypass after endo has failed, this is what all the results are going to start to look like. So let's be a little bit smarter. Now what about patency?

I think we, even today in the endovascular world, we realize patency is important. After all, that's why we're doing drug elution. Most, but not all patients with advanced limb ischemia will recrudesce their symptoms when their revascularization fails.

I think we all know that. Most CLTI patients have multi-segment disease. I don't want to sit up here and be a high school or elementary school math teacher, but here's the reality. If you look at it above the lesion, you say I'm going to get 70 percent patency there, and you look at

the tibial lesion, you say I'm going to get 50 percent patency there, what do you think your patency is for the whole leg? It's 35 percent folks, it's the product of the two. That is the reality pretty often. Patients with more advanced limb presentations,

such as WIfI stage do not tolerate these failures. They tolerate them poorly. They go on to amputation pretty fast. And patient survival, as I've already shown you has improved. Now, what the all endo-all the time

camp does and doesn't say. He already showed us, many datasets suggest the downstream outcomes are roughly equivalent but, these are not the same patients, we are not operating on the same patients you are doing endo on.

If I told you the results are the same for PCI and CABG without showing you anatomy, you would laugh me off the stage right? So, this is really not an equivalent argument. Endo can be repeated with minimal morbidity, but patients suffer.

Their limb status deteriorates, they come in the hospital often, and they continue to decline in the outcomes of these secondary procedures. CLTI patients are too frail for surgery, I just showed you that's really not true for many patients.

There is really unfortunately, an economic incentive here. Because there is unfortunately, no incentive for durable success. I hate to bring that up, but that's the reality. Now just quickly, some results. This is a large Japanese series

where they were performing endovascular interventions only for advanced limb ischemia. And basically what you can see as you go across the WIfI stages here from stage one to stage four, when you get to these stage four patients, the wound healing rate's only 44 percent,

limb salvage rate drops to 80 percent, repeat EVT rate is encroaching 50 percent. These patients really are not doing well with endovascular intervention. And we found that in our own series too, it's relatively small numbers and not randomized.

But if we look at the stage 4 limbs with bypass versus endo, when these patients failed at revascularization, and they may not have been bypass candidates, but they didn't do well, they went on to amputation very quickly.

So the ESC guidelines that just came out really sort of line up with what I'm telling you. You'll see bypass first. If you have long occlusions in an available vein, is actually currently the favorite approach, with level 1A recommendation.

So in summary, this is how I currently approach it. You look at all these factors, some people should get endo first, but there's still about 20 or 30 percent that I think should get bypass. Some people should go on to amputation earlier, is the bottom line, and I'll go right to the bottom line.

If you don't have access to a skilled open bypass surgeon, you're probably not at a center of excellence, go find one.

- Thank you very much and I would like to thank Dr. Veit for the kind invitation, this is really great meeting. Those are my disclosures. Percutaneous EVAR has been first reported in the late 1990's. However, for many reasons it has not been embraced

by the vascular community, despite the fact that it has been shown that the procedure can be done under local anesthesia and it decreases OR time, time to ambulation, wound complication and length of stay. There are three landmark papers which actually change this trend and make PEVAR more popular.

All of these three papers concluded that failure or observed failure of PEVAR are observed and addressed in the OR which is a key issue. And there was no late failures. Another paper which is really very prominent

is a prospective randomize study that's reported by Endologix and published in 2014. Which revealed that PEVAR closure of the arteriotomy is not inferior to open cut down. Basically, this paper also made it possible for the FDA to approve the device, the ProGlide device,

for closure of large bore arteriotomies, up to 26 in the arterial system and 29 in the venous system. We introduced percutaneous access first policy in our institution 2012. And recently we analyzed our results of 272 elective EVAR performed during the 2012 to 2016.

And we attempted PEVAR in 206 cases. And were successful in 92% of cases. But the question was what happened with the patient that failed PEVAR? And what we found that was significantly higher thrombosis, vessel thrombosis,

as well as blood loss, more than 500 cc in the failed PEVAR group. Similarly, there was longer operative time and post-operative length of stay was significantly longer. However, in this relatively small group of patients who we scheduled for cut-down due to different reasons,

we found that actually there was no difference between the PEVAR and the cut-down, failed PEVAR and cut-down in the terms of blood loss, thrombosis of the vessel, operative time and post-operative length of stay. So what are the predictors of ProGlide failure?

Small vessel calcification, particularly anterior wall calcification, prior cut-down and scarring of the groin, high femoral bifurcation and use of large bore sheaths, as well as morbid obesity. So how can we avoid failures?

I think that the key issue is access. So we recommend that all access now or we demand from our fellow that when we're going to do the operation with them, cut-down during fluoroscopy on the ultra-sound guidance, using micropuncture kits and access angiogram is actually mandatory.

But what happened when there is a lack of hemostasis once we've deployed two PEVARs? Number one, we try not to use more than three ProGlide on each side. Once the three ProGlide failed we use the angioseal. There's a new technique that we can have body wire

and deployed angioseal and still have an access. We also developed a technique that we pack the access site routinely with gelfoam and thrombin. And also we use so-called pull and clamp technique, shown here. Basically what it is, we pull the string of the ProGlide

and clamp it on the skin level. This is actually a very very very good technique. So in conclusion, PEVAR first approach strategy successful in more than 90% of cases, reduced operative time and postoperative length of stay, the failure occurred more commonly when the PEVAR

was completed outside of IFU, and there was no differences in outcome between failed PEVAR and planned femoral cut-down. Thank you.

- Thank you, Dr. Ascher. Great to be part of this session this morning. These are my disclosures. The risk factors for chronic ischemia of the hand are similar to those for chronic ischemia of the lower extremity with the added risk factors of vasculitides, scleroderma,

other connective tissue disorders, Buerger's disease, and prior trauma. Also, hemodialysis access accounts for a exacerbating factor in approximately 80% of patients that we treat in our center with chronic hand ischemia. On the right is a algorithm from a recent meta-analysis

from the plastic surgery literature, and what's interesting to note is that, although sympathectomy, open surgical bypass, and venous arterialization were all recommended for patients who were refractory to best medical therapy, endovascular therapy is conspicuously absent

from this algorithm, so I just want to take you through this morning and submit that endovascular therapy does have a role in these patients with digit loss, intractable pain or delayed healing after digit resection. Physical examination is similar to that of lower extremity, with the added brachial finger pressures,

and then of course MRA and CTA can be particularly helpful. The goal of endovascular therapy is similar with the angiosome concept to establish in-line flow to the superficial and deep palmar arches. You can use an existing hemodialysis access to gain access transvenously to get into the artery for therapy,

or an antegrade brachial, distal brachial puncture, enabling you treat all three vessels. Additionally, you can use a retrograde radial approach, which allows you to treat both the radial artery, which is typically the main player in these patients, or go up the radial and then back over

and down the ulnar artery. These patients have to be very well heparinized. You're also giving antispasmodic agents with calcium channel blockers and nitroglycerin. A four French sheath is preferable. You're using typically 014, occasionally 018 wires

with balloon diameters 2.3 to three millimeters most common and long balloon lengths as these patients harbor long and tandem stenoses. Here's an example of a patient with intractable hand pain. Initial angiogram both radial and ulnar artery occlusions. We've gone down and wired the radial artery,

performed a long segment angioplasty, done the same to the ulnar artery, and then in doing so reestablished in-line flow with relief of this patient's hand pain. Here's a patient with a non-healing index finger ulcer that's already had

the distal phalanx resected and is going to lose the rest of the finger, so we've gone in via a brachial approach here and with long segment angioplasty to the radial ulnar arteries, we've obtained this flow to the hand

and preserved the digit. Another patient, a diabetic, middle finger ulcer. I think you're getting the theme here. Wiring the vessels distally, long segment radial and ulnar artery angioplasty, and reestablishing an in-line flow to the hand.

Just by way of an extreme example, here's a patient with a vascular malformation with a chronically occluded radial artery at its origin, but a distal, just proximal to the palmar arch distal radial artery reconstitution, so that served as a target for us to come in

as we could not engage the proximal radial artery, so in this patient we're able to come in from a retrograde direction and use the dedicated reentry device to gain reentry and reestablish in-line flow to this patient with intractable hand pain and digit ulcer from the loss of in-line flow to the hand.

And this patient now, two years out, remains patent. Our outcomes at the University of Pennsylvania, typically these have been steal symptoms and/or ulceration and high rates of technical success. Clinical success, 70% with long rates of primary patency comparing very favorably

to the relatively sparse literature in this area. In summary, endovascular therapy can achieve high rates of technical, more importantly, clinical success with low rates of major complications, durable primary patency, and wound healing achieved in the majority of these patients.

Thank you.

- Thank you very much for inviting me here again and I'll be talking about thermal ablation RCTs. My coauthor, Michel Perrin from Lyon, in France, the gourmet capital in the world has collected RCTs on operative treatment of CVD since 1990. Today he has 186 collected RCTs

of the which 84 involve thermal ablation. You can find all this data for free in Phlebolymphology.org. Do we need further RCTs? Well systematic reviews and meta-analyses increasingly important in evidence-based medicine. And this development is well-described

by Gurevitch in Nature this year and criticized by Ioannidis two years earlier. Common sense is a good principle when you try to understand meta-analyses. Do most studies point in the same direction?

Is the effect significant? Are the patient-related outcome measures relevant and what happens if you exclude one study? Since 2008, 10 years back, these are the available meta-analyses and the last came from Ireland earlier this year.

It was published in the JVS, endovenous and in fact this is in March. And they found nine RCTs comparing conventional surgery and endovenous therapy with five years or more follow-up that were selected. Primary outcome was recurrence rate.

There is some sole recurrence rate was that there is no significant difference in laser versus surgery, same for radioactive frequency versus surgery and radioactive frequency versus laser. They found an inferiority

of ultrasound guided foam sclerotherapy versus laser and surgery. Their conclusions were that the quality of evidence is poor therefore more trials that are well-powered to examine long-term outcomes are warranted. The new kids on the block,

steam, MOCA, and Venaseal, are not included in the meta-analyses due to lack of more than five years follow-up in their paper. Obsolete RCTs. Endovenous laser in the presented long-term RCTs

were performed by 810-980 nanometer wavelength using a bare fiber. There is a paucity of RCTs comparing open surgery with novel endovenous laser and new RF techniques. Recent criticism against endovenous ablation, is the pendulum swinging towards high ligation

and stripping again? Olle Nelzen from Sweden in an editorial in British Journal of Surgery reconsidering the endovenous revolution, wrote that neovascularization is a dominant finding following high ligation and stripping

but proximal venous stumps and incompetent anterior accessory saphenous veins are the main factor after endovenous ablation. So long-term follow-up suggests that the recurrence rate after endovenous ablation seem to increase over time. A substantial number of patients who have undergone

endovenous ablation will eventually develop symptomatic recurrence requiring repeat therapy. And such scenario would change the equation regarding patient benefit and costs making endovenous ablation less competitive and challenging current guidelines.

So summary of needs for further RCTs. Quality of present RCTs poor in several meta-analyses, no thermal endovenous technique is superior to open surgery, RCTs rapidly obsolete due to change in technology, and more trials that are well-powered to examine long-term outcomes are warranted.

So final point, apparently we need more RCTs to satisfy the quality requirements for clinically important systematic reviews and meta-analyses. And what about the clinical guidelines? Thank you very much.

- I'd like to thank Dr. Veith for this kind invitation and the committee as well. So these are my disclosures, there's none. So for a quick background regarding closure devices. Vascular closure devices have been around

for almost 20 years, various types. Manual compression in most studies have always been shown to be superior to vascular closure devices mainly because there's been no ideal device that's been innovated to be able

to handle all sorts of anatomies, which include calcified vessels, soft plaque, etc. So in this particular talk we wanted to look at to two particular devices. One is the Vascade vascular closure device

made by Cardiva and the other is the CELT arterial closure device made by Vasorum in Ireland. Both these devices are somewhat similar in that they both use a disc. The Vascade has a nitinol disc

as you can see here that's used out here to adhere to the interior common femoral artery wall. And then once tension is applied, a series of steps is involved to deploy the collagen plug

directly on to the artery which then allows it to expand over a period of time. The CELT is similar in that it also uses a stainless steel disc as you can see here. Requires tension up against the interior wall of the common femoral artery.

Nice and tight and then you screw on the top end of the device on to the interior wall of the artery creating a nice little cylinder that compresses both walls of artery. As far as comparability is concerned between the two devices you can see

here that they're both extravascular, one's nitinol, one's stainless steel. One uses a collagen material, the other uses an external clip in a spindle-type fashion. Both require about, anywhere between three to seven minutes of pressure

to essentially stop the tract ooze. But the key differences between the two devices, is the amount of time it takes for patients to ambulate. So the ambulation time is two hours roughly for Vascade, whereas for a CELT device

it's anywhere from being immediate off the table at the cath lab room to about 20 minutes. The data for Vascade was essentially showing the RESPECT trial which I'll summarize here, With 420 patients that was a randomized trial

to other manual compression or the device itself. The mean points of this is that the hemostasis time was about three minutes versus 21 minutes for manual compression. And time to ambulation was about 3.2 hours versus 5.7 hours.

No major complications were encountered. There were 1.1% of minor complications in the Vascade versus 7% in the manual compression arm. This was actually the first trial that showed that a actual closure devices

had better results than manual compression. The main limitations in the trial didn't involved complex femoral anatomy and renal insufficiency patients which were excluded. The CELT ACD trial involved 207 patients that were randomized to CELT or to manual

compression at five centers. Time to hemostasis was anywhere between zero minutes on average versus eight minutes in the manual compression arm. There was one complication assessed at 30 days and that was a distal embolization that occurred

early on after the deployment with a successfully retrieved percutaneously with a snare. So complication rate in this particular trial was 0.7% versus 0% for manual compression. So what are some pros and cons with the Vascade device?

Well you can see the list of pros there. The thing to keep in mind is that it is extravascular, it is absorbable, it's safe, low pain tolerance with this and the restick is definitely possible. As far as the cons are involved.

The conventional bedrest time is anywhere between two to three hours. It is a passive closure device and it can create some scarring when surgical exploration is necessary on surgical dissections.

The key thing also is you can not visualize the plug after deployment. The pros and cons of the CELT ACD device. You can see is the key is the instant definitive closure that's achieved with this particular device, especially in

calcified arteries as well. Very easy to visualize under fluoroscopy and ultrasound. It can be used in both antegrade and retrograde approaches. The key cons are that it's a permanent implant.

So it's like a star closed devised, little piece of stainless steel that sits behind. There's a small learning curve with the device. And of course there's a little bit of discomfort associated with the cinching under the (mumbles) tissue.

So we looked at our own experience with both devices at the Christie Clinic. We looked at Vascade with approximately 300 consecutive patients and we assessed their time to hemostasis, their time to ambulation,

and their time to discharge, as well as the device success and minor and major complications. And the key things to go over here is that the time to hemostasis was about 4.7 minutes for Vascade, at 2.1 hours for ambulation, and roughly an average

of 2.4 hours for discharge. The device success was 99.3% with a minor complication rate of .02% which we have four hematomas and two device failures requiring manual compression. The CELT ACD device we also similarly did

a non-randomized perspective single center trial assessing the same factors and assessing the patients at seven days. We had 400 consecutive patients enrolled. And you can see we did 232 retrograde. We did a little bit something different

with this one, we did we 168 antegrade but we also did direct punctures to the SFA both at the proximal and the mid-segments of the SFA. And the time to hemostasis in this particular situation was 3.8 minutes,

ambulation was 18.3 minutes, and discharge was at 38.4 minutes. We did have two minor complications. One of which was a mal-deployment of the device requiring manual compression. And the second one was a major complication

which was an embolization of the device immediately after deployment which was done successfully snared through an eighth front sheath. So in conclusion both devices are safe and effective and used for both

antegrade and retrograde access. They're definitely comparable when it comes, from the standpoint of both devices (mumbles) manual compression and they're definitely really cost effective in that they definitely do increase the

throughput in the cath lab allowing us to be able to move patients through our cath lab in a relatively quick fashion. Thank you for your attention.

- Mr. Chairman, ladies and gentlemen, good morning. I'd like to thank Dr. Veith for the opportunity to present at this great meeting. I have nothing to disclose. Since Dr. DeBakey published the first paper 60 years ago, the surgical importance of deep femoral artery has been well investigated and documented.

It can be used as a reliable inflow for low extremity bypass in certain circumstances. To revascularize the disease, the deep femoral artery can improve rest pain, prevent or delay the amputation, and help to heal amputation stump.

So, in this slide, the group patient that they used deep femoral artery as a inflow for infrainguinal bypass. And 10-year limb salvage was achieved in over 90% of patients. So, different techniques and configurations

of deep femoral artery angioplasty have been well described, and we've been using this in a daily basis. So, there's really not much new to discuss about this. Next couple minutes, I'd like to focus on endovascular invention 'cause I lot I think is still unclear.

Dr. Bath did a systemic review, which included 20 articles. Nearly total 900 limbs were treated with balloon angioplasty with or without the stenting. At two years, the primary patency was greater than 70%. And as you can see here, limb salvage at two years, close to, or is over 98% with very low re-intervention rate.

So, those great outcomes was based on combined common femoral and deep femoral intervention. So what about isolated deep femoral artery percutaneous intervention? Does that work or not? So, this study include 15 patient

who were high risk to have open surgery, underwent isolated percutaneous deep femoral artery intervention. As you can see, at three years, limb salvage was greater than 95%. The study also showed isolated percutaneous transluminal

angioplasty of deep femoral artery can convert ischemic rest pain to claudication. It can also help heal the stump wound to prevent hip disarticulation. Here's one of my patient. As you can see, tes-tee-lee-shun with near

or total occlusion of proximal deep femoral artery presented with extreme low-extremity rest pain. We did a balloon angioplasty. And her ABI was increased from 0.8 to 0.53, and rest pain disappeared. Another patient transferred from outside the facility

was not healing stump wound on the left side with significant disease as you can see based on the angiogram. We did a hybrid procedure including stenting of the iliac artery and the open angioplasty of common femoral artery and the profunda femoral artery.

Significantly improved the perfusion to the stump and healed wound. The indications for isolated or combined deep femoral artery revascularization. For those patient presented with disabling claudication or rest pain with a proximal

or treatable deep femoral artery stenosis greater than 50% if their SFA or femoral popliteal artery disease is unsuitable for open or endovascular treatment, they're a high risk for open surgery. And had the previous history of multiple groin exploration, groin wound complications with seroma or a fungal infection

or had a muscle flap coverage, et cetera. And that this patient should go to have intervascular intervention. Or patient had a failed femoral pop or femoral-distal bypass like this patient had, and we should treat this patient.

So in summary, open profundaplasty remains the gold standard treatment. Isolated endovascular deep femoral artery intervention is sufficient for rest pain. May not be good enough for major wound healing, but it will help heal the amputation stump

to prevent hip disarticulation. Thank you for much for your attention.

- This talk is a brief one about what I think is an entity that we need to be aware of because we see some. They're not AVMs obviously, they're acquired, but it nevertheless represents an entity which we've seen. We know the transvenous treatment of AVMs is a major advance in safety and efficacy.

And we know that the venous approach is indeed very, very favorable. This talk relates to some lesions, which we are successful in treating as a venous approach, but ultimately proved to be,

as I will show you in considerable experience now, I think that venous thrombosis and venous inflammatory disease result in acquired arteriovenous connections, we call them AVMs, but they're not. This patient, for example,

presented with extensive lower extremity swelling after an episode of DVT. And you can see the shunting there in the left lower extremity. Here we go in a later arterial phase. This lesion we found,

as others, is best treated. By the way, that was his original episode of DVT with occlusion. Was treated with stenting and restoration of flow and the elimination of the AVM.

So, compression of the lesion in the venous wall, which is actually interesting because in the type perivenous predominant lesions, those are actually lesions in the vein wall. So these in a form, or in a way, assimilate the AVMs that occur in the venous wall.

Another man, a 53-year-old gentleman with leg swelling after an episode of DVT, we can see the extensive filling via these collaterals, and these are inflammatory collaterals in the vein wall. This is another man with a prior episode of DVT. See his extensive anterior pelvic collaterals,

and he was treated with stenting and success. A recent case, that Dr. Resnick and I had, I was called with a gentleman said he had an AVM. And we can see that the arteriogram sent to me showed arterial venous shunting.

Well, what was interesting here was that the history had not been obtained of a prior total knee replacement. And he gave a very clear an unequivocal history of a DVT of sudden onset. And you can see the collaterals there

in the adjacent femoral popliteal vein. And there it is filling. So treatment here was venous stenting of the lesion and of the underlying stenosis. We tried an episode of angioplasty,

but ultimately successful. Swelling went down and so what you have is really a post-inflammatory DVT. Our other vast experience, I would say, are the so-called uterine AVMs. These are referred to as AVMs,

but these are clearly understood to be acquired, related to placental persistence and the connections between artery and veins in the uterus, which occurs, a part of normal pregnancy. These are best treated either with arterial embolization, which has been less successful,

but in some cases, with venous injection in venous thrombosis with coils or alcohol. There's a subset I believe of some of our pelvic AVMs, that have histories of DVT. I believe they're silent. I think the consistency of this lesion

that I'm showing you here, that if we all know, can be treated by coil embolization indicates to me that at least some, especially in patients in advanced stage are related to DVT. This is a 56-year-old, who had a known history of prostate cancer

and post-operative DVT and a very classic looking AVM, which we then treated with coil embolization. And we're able to cure, but no question in my mind at least based on the history and on the age, that this was post-phlebitic.

And I think some of these, and I think Wayne would agree with me, some of these are probably silent internal iliac venous thromboses, which we know can occur, which we know can produce pulmonary embolism.

And that's the curative final arteriogram. Other lesions such as this, I believe are related, at least some, although we don't have an antecedent history to the development of DVT, and again of course,

treated by the venous approach with cure. And then finally, some of the more problematic ones, another 56-year-old man with a history of prior iliofemoral DVT. Suddenly was fine, had been treated with heparin and anticoagulation.

And suddenly appeared with rapid onset of right lower extremity swelling and pain. So you see here that on an arteriogram of the right femoral, as well as, the super selective catheterization of some of these collaterals.

We can see the lesion itself. I think it's a nice demonstration of lesion. Under any other circumstance, this is an AVM. It is an AVM, but we know it to be acquired because he had no such swelling. This was treated in the only way I knew how to treat

with stenting of the vein. We placed a stent. That's a ballon expanded in the angiogram on your right is after with ballon inflation. And you can see the effect that the stenting pressure, and therefore subsequently occlusion of the compression,

and occlusion of the collaterals, and connections in the vein wall. He subsequently became asymptomatic. We had unfortunately had to stent extensively in the common femoral vein but he had an excellent result.

So I think pelvic AVMs are very similar in location and appearance. We've had 13 cases. Some with a positive history of DVT. I believe many are acquired post-DVT, and the treatment is the same venous coiling and or stent.

Wayne has seen some that are remarkable. Remember Wayne we saw at your place? A guy was in massive heart failure and clearly a DVT-related. So these are some of the cases we've seen

and I think it's noteworthy to keep in mind, that we still don't know everything there is to know about AVMs. Some AVMs are acquired, for example, pelvic post-DVT, and of course all uterine AVMs. Thanks very much.

(audience applause) - [Narrator] That's a very interesting hypothesis with a pelvic AVMs which are consistently looking similar. - [Robert] In the same place right? - [Narrator] All of them are appearing at an older age. - [Robert] Yep.

Yep. - This would be a very, very good explanation for that. I've never thought about that. - Yeah I think-- - I think this is very interesting. - [Robert] And remember, exactly.

And I remember that internal iliac DVT is always a silent process, and that you have this consistency, that I find very striking. - [Woman] So what do you think the mechanism is? The hypervascularity looked like it was primarily

arterial fluffy vessels. - [Robert] No, no, no it's in the vein wall. If you look closely, the arteriovenous connections and the hypervascularity, it's in the vein wall. The lesion is the vein wall,

it's the inflammatory vein. You remember Tony, that the thing that I always think of is how we used to do plain old ballon angioplasty in the SFA. And afterwards we'd get this

florid venous filling sometimes, not every case. And that's the very tight anatomic connection between those two. That's what I think is happening. Wayne? - [Wayne] This amount is almost always been here.

We just haven't recognized it. What has been recognized is dural fistula-- - Yep. - That we know and that's been documented. Chuck Kerber, wrote the first paper in '73 about the microvascular circulation

in the dural surface of the dural fistula, and it's related to venous thrombosis and mastoiditis and trauma. And then as the healing process occurs, you have neovascular stimulation and fistulization in that dural reflection,

which is a vein wall. And the same process happens here with a DVT with the healing, the recanalization, inflammation, neovascular stimulation, and the development of fistulas. increased vascular flow into the lumen

of the thrombosed area. So it's a neovascular stimulation phenomenon, that results in the vein wall developing fistula very identical to what happens in the head with dural fistula had nothing described of in the periphery.

- [Narrator] Okay, very interesting hypothesis.

- So I'd like to thank Dr. Ascher, Dr. Sidawy, Dr. Veith, and the organizers for allowing us to present some data. We have no disclosures. The cephalic arch is defined as two centimeters from the confluence of the cephalic vein to either the auxiliary/subclavian vein. Stenosis in this area occurs about 39%

in brachiocephalic fistulas and about 2% in radiocephalic fistulas. Several pre-existing diseases can lead to the stenosis. High flows have been documented to lead to the stenosis. Acute angles. And also there is a valve within the area.

They're generally short, focal in nature, and they're associated with a high rate of thrombosis after intervention. They have been associated with turbulent flow. Associated with pre-existing thickening.

If you do anatomic analysis, about 20% of all the cephalic veins will have that. This tight anatomical angle linked to the muscle that surrounds it associated with this one particular peculiar valve, about three millimeters from the confluence.

And it's interesting, it's common in non-diabetics. Predictors if you are looking for it, other than ultrasound which may not find it, is calcium-phosphate product, platelet count that's high, and access flow.

If one looks at interventions that have commonly been reported, one will find that both angioplasty and stenting of this area has a relatively low primary patency with no really discrimination between using just the balloon or stent.

The cumulative patency is higher, but really again, deployment of an angioplasty balloon or deployment of a stent makes really no significant difference. This has been associated with residual stenosis

greater than 30% as one reason it fails, and also the presence of diabetes. And so there is this sort of conundrum where it's present in more non-diabetics, but yet diabetics have more of a problem. This has led to people looking to other alternatives,

including stent grafts. And in this particular paper, they did not look at primary stent grafting for a cephalic arch stenosis, but mainly treating the recurrent stenosis. And you can see clearly that the top line in the graph,

the stent graft has a superior outcome. And this is from their paper, showing as all good paper figures should show, a perfect outcome for the intervention. Another paper looked at a randomized trial in this area and also found that stent grafts,

at least in the short period of time, just given the numbers at risk in this study, which was out after months, also had a significant change in the patency. And in their own words, they changed their practice and now stent graft

rather than use either angioplasty or bare-metal stents. I will tell you that cutting balloons have been used. And I will tell you that drug-eluting balloons have been used. The data is too small and inconclusive to make a difference. We chose a different view.

We asked a simple question. Whether or not these stenoses could be best treated with angioplasty, bare-metal stenting, or two other adjuncts that are certainly related, which is either a transposition or a bypass.

And what we found is that the surgical results definitely give greater long-term patency and greater functional results. And you can see that whether you choose either a transposition or a bypass, you will get superior primary results.

And you will also get superior secondary results. And this is gladly also associated with less recurrent interventions in the ongoing period. So in conclusion, cephalic arch remains a significant cause of brachiocephalic AV malfunction.

Angioplasty, across the literature, has poor outcomes. Stent grafting offers the best outcomes rather than bare-metal stenting. We have insufficient data with other modalities, drug-eluting stents, drug-eluting balloons,

cutting balloons. In the correct patient, surgical options will offer superior long-term results and functional results. And thus, in the good, well-selected patient, surgical interventions should be considered

earlier in this treatment rather than moving ahead with angioplasty stent and then stent graft. Thank you so much.

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